DE4039676C1 - Draught control flap for flue - incorporates counterbalance weight and brake to prevent sudden movements - Google Patents

Abstract

The draught control flap pivots in an ancillary flue gas entry and opens from closed against a restoring force under the effect of the pressure gradient between flue and surrounding room. A brake (38) engaging the flap (32) brakes this down as the flap speed rises. Pref. the braking force is partly or totally suppressed in a path area adjoining closure. The brake is of the fluid type composed of two choke-linked chambers changing reciprocally in volume during flap movement. USE/ADVANTAGE - Domestic fireplaces etc. Draught control flap with brake responds closely to pressure changes, and is proof against sudden wind blasts etc.

Description

The invention relates to a train limiting device for the Exhaust gas path of a fireplace, including one in a secondary air leave the exhaust path arranged to pivot about a pivot axis Flap, which under the effect of the pressure prevailing on it difference between the pressure in the exhaust gas path and the pressure in the um the exhaust gas path from a closed position against one Restoring torque adjustable in the direction of an open position is.

Such a train limiting device is known from the DE-PS 30 30 131.

The one on the flap between the exhaust gas path on the one hand and the order space of the exhaust gas path on the other hand occurring pressure differences limits that are intended to control the flap position are extremely low and are in the order of 5-40 Pa.  

Accordingly, the flap must be mounted so that it moves smoothly it responds sensitively to pressure differences and their determinants the amount of secondary air in the exhaust gas path can flow that the pressure in the exhaust gas path at the point of Zugbe limiting device is kept approximately constant.

The flap shown and described in DE-PS 30 30 131 has proven to be excellent on the whole in practice. Nevertheless, an appearance has now been identified which leads to a gave cause for further improvement:

If the fire equipped with the train limiting device is in operation, the flap is regularly in one Intermediate position between the closed position and the fully open position set by the pressure difference. Now go that Fireplace out of order, for example because no heat is required If there is more change to the fireplace, the Draft control device within the exhaust gas path a shock-like Pressure reduction on. This surge pressure reduction is on it attributable to the fact that a strong exhaust gas mass continues in the chimney electricity takes place, but no exhaust gas masses from the fireplace more will be delivered. This abrupt reduction will Fan burners are reinforced by the fact that these fan burners are equipped with air flaps, which when the Close the fan burner so that no fresh air is in can get the exhaust gas path.

It has been found that as a result of such sudden pressure Reductions in the exhaust gas path, the respective flap a bump-like Experienced acceleration towards the fully open position. It has been shown that this sudden acceleration Damage and destruction of the flap or associated parts can lead. This applies in particular to larger systems correspondingly large exhaust gas mass flows. Here was in particular found that the 30 30 131  adjustment weights provided for balancing the flap lead to changes in position that lead to the flap can lead to a control disorder. In an extreme case, there was even one Separation of these weights from the flap was found.

Excessive acceleration can also occur when the fireplace starts up the flap. One has to imagine that at The flap usually stands still slightly is open as long as there is a chimney draft. If so Fireplace goes into operation, so builds up inside the exhaust gas an overpressure that leads to a jerky Closing the flap leads. This abrupt closing of the Flap can lead to the pre-set for flap adjustment seen weights change their position opposite the flap and thus the control characteristic of the flap in an undesirable manner is changed.

The invention has for its object stress-like closing and opening movements to completely or largely prevent the pivoting flap.

To solve this problem, the invention proposes that on the flap a braking device engages the movement the flap with increasing movement speed of the flap increasing braking force brakes.

The inventive design of the braking device such that with increasing movement speed of the flap an increasing Braking force applied to the flap is of crucial importance of importance for the functioning of the train limitation direction. With slow movements of the flap, as in the the braking effect is low or practically turned off. The flap can therefore be sensitive on pressure fluctuations in the exhaust gas path and resulting ones Address pressure differential fluctuations. On the other hand, the Braking effect with increasing flap movement speed  larger, so that oversized flap speeds and acceleration are prevented.

It has been found that the training of the invention Train limiting device also makes it noticeably noticeable, when high-frequency interference, for example due to gusts of wind in the Area of the chimney outlet. Such high-frequency interference could also lead to undesirable acceleration of the flap to lead. These are also due to the brake assigned to the flap facility prevented.

With regard to the highest possible sensitivity of the flap for low pressure differences between the exhaust gas path and the environment recommended that the braking force be in one of the closed positions neighboring area of movement of the flap completely or partially under presses.

A fluid braking device is preferred as the braking device suggested with at least two depending on the Flap movement of fluid chambers that can be changed in opposite directions, which are connected by a throttled connection are.

Such a braking device usually has a non-linear increasing braking effect with increasing valve speed. Such a characteristic has become for braking devices in the Use in train limiting devices as particularly advantageous proven.

The demand for the lowest possible initial braking torque (This is the braking torque for small flaps that approach zero speeds) can be done relatively easily meet that the braking device one with the flap for common pivotal movement connected rotor and a stationary arranged stator comprises, through the rotor and the stator the at least two fluid chambers are limited.  

The friction between the rotor and the stator can namely also taking into account the necessary dynamic seals be kept low. For example, a design apply, in which the stator of a cylindrical housing is formed with radially arranged stator partitions and the rotor is designed with rotor blade elements, which together limit the fluid chambers with the stator partitions.

The braking characteristics of the braking device can still be adapt better to the respective application in that the throttled fluid connection depending on the flap cross section is variable. In this way it is possible that the cross section of the fluid connection in one to the Flap closed position towards flap open position adjacent movement area is dimensioned so large that the Braking effect is essentially suppressed. But it is think bar that the cross section of the fluid connection on a larger Part of the Klappenweg, possibly even the entire way Klappenweg is variable, so that any way Braking characteristics can be generated.

It is just a question of braking action by closing the flap position immediately adjacent to the range of motion press, this can be done in that between the fluid chambers in the area of the closed position of the flap a short final stretch is formed. This short circuit can be about formed by a recess in the peripheral wall of the stator be where this peripheral wall is when the flap moves from a radially outer boundary edge of a rotor blade element is swept over.  

Although the flow resistance through the fluid connection even with increasing movement speed of the flap increases regularly when the cross section of the fluid compound remains constant, it can be particularly useful for achieving favorable characteristics can be advantageous if the ge throttled fluid connection depending on the Ge cross-sectional velocity of the flap movement is.

Then it is particularly possible to use a steep cross-section reduce the speed of movement of the flap and thus increasing the braking effect.

Such an embodiment can be obtained in that the throttled fluid connection by at least one Throttle element is cross-sectional controlled, which is the pressure in one of the oppositely volume-changing fluid chambers is exposed such that with increasing pressure in this Fluid chamber the throttle element the cross section of the ge throttled connection decreased. In this embodiment it is ensured that at least in one direction of motion tion of the flap with increasing speed of movement strongly progressive change in braking torque occurs.

If you want a strong for both directions of movement of the flap provide progressively increasing braking torque, so this is done by making the throttled connection ever a throttle element in each of the two connected by it Fluid chambers is assigned. The opening and closing characteristics of the two throttle elements can be the same or different, so that one after Desires in different directions of movement of the flap different braking torque curve depending on can bring about the movement speed of the flap.  

A particularly simple embodiment of a throttle element is that the throttle element of an elastic Platelet is formed, which against its own elasticity verity by the pressure in the associated fluid chamber is adjustable.

Although it is basically conceivable to use the braking device to operate a gaseous fluid, such as air proved to be advantageous when the braking device is a fluid brake device. With a liquid Braking device can be a small design achieve sufficient braking effect.  

The train limiting device is in terms of a ge desired control characteristic precisely balanced by appropriate Dimensioning and positioning of counterweights or off equal springs. To this Austa when mounting a braking device ration not to be disturbed, it is suggested that the focus the masses of the braking device movable with the flap with the Pivot axis of the braking device at least approximately together falls. This training is particularly advantageous if the braking device is retrofitted as an accessory because then it is not necessary to refurbish the flap.

Especially with regard to the retrofit problem, but also in With regard to the simplified production in the manufacturing plant it is beneficial if the rotor and the stator have a previous month Formed unit, which with the Zugbegrenzungseinrich device is connectable. The assembly of the pre-assembled unit becomes particularly easy when the rotor is inserted through a first plug connection can be plugged onto a swivel shaft of the flap and at the same time a torque arm of the stator by a second one Plug connection with a frame of the train limiting device is connectable.

The figures explain the invention using a Embodiment; it represents:

Figure 1 is a schematic overview of a Zugbegrenzungsein direction according to the invention.

Fig. 2 is a section along line II-II of Fig. 1;

Fig. 3 shows the circuit diagram of a fireplace including a fireplace to equip with a Zugbegren invention device;

Fig. 4 is a detailed view of Fig. 1 showing the rotor of a braking device in a modified embodiment.

In Fig. 3 you can see a fireplace, which is generally designated 10 and is equipped with a forced air burner 12 . A supply air flap 14 is assigned to the fan burner 12 and is opened and closed, for example, depending on the electrical control of the fan burner. To the hearth 10, for example a gas appliance 10, an exhaust pipe 16 connects, which opens into a chimney 18th At the exhaust pipe 16 , a cross tube 20 is attached, which is completed by an end plate 22 . On the end plate 22 , a train limiting device 24 is attached. The Zugbegrenzungsein device 24 is shown in detail in Fig. 1. A frame 26 is to be understood as part of the end plate 22 . On this frame, a pivot shaft 30 is mounted in bearings 28 on which a flap 32 is rotatably attached. The flap 32 is provided in its upper region with a spatial diaphragm 34 which interacts with the frame 26 in such a way that the region of the frame 26 above the pivot shaft 30 is always closed, regardless of the flap position. Because of closer details of the flap training reference is made to DE-PS 30 30 131. A balance weight 36 is also connected to the pivot shaft 30 , which allows the position of the center of gravity of the flap and thus the control behavior of the flap to be set. Also for details of this setting, reference can be made to DE-PS 30 30 131.

A brake device 38 is attached to the pivot shaft 30 and, as can also be seen in FIG. 2, consists of a cylindrical stator 40 and a rotor 42 . The stator 40 is designed with two stator partitions 40 a, which extend up to the rotor 42 , while the rotor 42 is provided with two rotor blade elements 42 a, which extend up to the inner peripheral wall 40 b of the cylindri's housing 40 . Work cells 44 I and 44 II are attached between the stator partitions 40 a and the rotor wing elements 42 a. Each work cell 44 I is connected to a work cell 44 II by damping gaps which are formed on the inner peripheral wall 40 b and on the end walls of the cylindrical housing. Such a damping gap can be seen on the one rotor blade element 42 a in the position shown in dashed lines at 46 . The work cells 44 I and 44 II are filled with hydraulic fluid. When the rotor 42 rotates clockwise with the pivot shaft 30 relative to the cylindrical housing 40 , the volume of the work cells 44 I decreases, while the volume of the work cells 44 II increases. Accordingly, a throttled flow of the hydraulic fluid from the work cells 44 I into the work cells 44 II through the throttle column 46 takes place, and the rotational movement of the pivot shaft 30 is damped.

In Fig. 2, the position of the braking device 38 is shown, which speaks the closed position of the flap 32 according to FIG. 1 ent. In this position, the radially outer edges 42 a 1 are in register with recesses 40 b 1 on the inner circumference wall 40 b, so that the connection cross sections between the work cells 44 I and 44 II are greatly enlarged and no significant damping when the rotor rotates 42 takes place opposite the stator 40 . The flap 32 is essentially unaffected by the brake 38 in this area. If the edges 42 a 1 reach outside the area of the recesses 40 b 1 , a throttling effect occurs and the movement of the flap 32 is braked.

The braking device 38 is designed as a prefabricated structural unit which can be assembled as a unit with the train limiting device 24 . For this purpose, a first plug connection is provided between the pivot shaft 30 and the rotor 42 at 48 . A second connector 50 is seen between a torque arm 40 c of the stator 40 and the bearing 28 before. The two plug connections are made simultaneously.

According to FIG. 1, the flap 32 borders on the one hand on the space A within the exhaust pipe 16 and on the other hand on the space B, which corresponds to the ambient atmosphere. In normal operation, the flap 32 oscillates at a low pendulum speed. The recesses 40 b 1 can be exceeded by the rotor blade elements. Since the pendulum speed is low, the damping by the braking device 38 is also low. If a sudden vacuum occurs in space A, the flap 32 is accelerated in the direction of arrow 52 . Then the braking effect increases because the liquid has to pass through the damping gaps 46 at high speed. On the other hand, if an overpressure occurs in the room A when the furnace 10 is switched on, the flap 32 is accelerated in the direction of the arrow 54 towards its closed position, and the Bremseinrich device 38 is in turn effective with increased braking torque.

In FIG. 4 is a modified embodiment of the rotor 142 is illustrated. In this embodiment, the fluid connec tion between the chambers is formed by an opening 142 c of the rotor blade elements 142 a. Each of these openings 142 c two leaf spring-like throttle elements associated with d 142, a common rivet 142 are mounted e to the respective rotor blade member 142 by a respectively. If an overpressure occurs in a work cell 144 I, 144 II, the respective throttle element 142 d lies against the respective rotor blade element 142 a, so that the effective cross section of the respective opening 142 c is reduced.

In this embodiment, the rotor wing members 142 may a substantially without gaps the inside walls of the stator 40 face so that on the one hand at low Bewegungsgeschwin the flap speeds through the then large cross section of Publ voltages 142 c, the braking torque is substantially suppressed, while at higher speeds, the then small cross-sections of the openings 142 c are solely responsible for the fluid flow and deliver an exactly determinable strong progressive braking torque. The control accuracy of the braking device is thus greater than in the above-described embodiment, in which one had to make a compromise between the small braking effect at a slow movement speed and the large braking effect at high movement speed of the flap with regard to the gap 46 . The throttle body 142 d can be plastic plates, for example.

Claims (17)

1. draft limiting device for the exhaust gas path ( 16 , 18 ) of a fireplace ( 10 ), comprising a flap ( 32 ) which is arranged in a secondary air inlet of the exhaust gas path ( 16 , 18 ) and can be pivoted about a pivot axis and which, under the effect of the pressure difference prevailing thereon, between the Pressure in the exhaust gas path ( 16 , 18 ) and the pressure in the surrounding space (B) of the exhaust gas path ( 16 , 18 ) can be adjusted from a closed position against a restoring torque in the direction of an open position, characterized in that a braking device on the flap ( 32 ) ( 38 ) attacks which brakes the movement of the flap ( 32 ) with increasing movement speed of the flap ( 32 ) increasing braking force. 2. Train limiting device according to claim 1, characterized in that the braking force in one of the closed position adjacent movement range of the flap ( 32 ) is wholly or partially suppressed. 3. Draft limiting device according to one of claims 1 and 2, characterized in that the braking device ( 38 ) is a fluid braking device with at least two fluid chambers ( 44 I, 44 II) which can be changed in the opposite direction depending on the flap movement, which by a throttled connection ( 46 ) are interconnected. 4. Train limiting device according to claim 3, characterized in that the braking device ( 38 ) comprises a rotor ( 42 ) connected to the flap ( 32 ) for common pivoting movement and a stationary stator ( 40 ), with the rotor ( 42 ) and the Stator ( 40 ) the at least two fluid chambers ( 44 I, 44 II) are limited. 5. draft limiting device according to claim 4, characterized in that the stator ( 40 ) is formed by a cylindrical housing with radially arranged stator partitions ( 40 a) and that the rotor ( 42 ) with rotor blade elements ( 42 a) is executed, which together with the Stator partitions ( 40 a) limit the fluid chambers ( 44 I, 44 II). 6. Train limiting device according to one of claims 3 to 5, characterized in that the throttled connection ( 46 ) is variable in cross-section depending on the flap movement. 7. Train limiting device according to claim 6, characterized in that the cross section of the connection ( 46 ) in such a way that the movement of the flap adjacent to the closed position of the flap towards the open position of the flap is so large that the braking effect is substantially suppressed. 8. Train limiting device according to claim 7, characterized in that a short-circuit path ( 40 b 1 ) is formed between the fluid chambers ( 44 I, 44 II) in the region of the closed position of the flap. 9. Train limiting device according to claim 8, characterized in that the short-circuit path ( 40 b 1 ) is formed by a recess in the peripheral wall ( 40 b) of the stator ( 40 ) where this peripheral wall ( 40 b) when the flap ( 32 ) 1) a Rotorflü is gel element (42 a) swept by a radially outer boundary edge (42 a. 10. draft limiting device according to one of claims 3-9, characterized in that the throttled fluid connection ( 142 c) is variable in cross-section depending on the speed of the flap movement. 11. Train limiting device according to claim 10, characterized in that the throttled fluid connection ( 142 c) is cross-section-controlled by at least one throttle element ( 142 d) which is exposed to the pressure in one of the oppositely volume-variable fluid chambers ( 144 I, 144 II), such that that with increasing pressure in this fluid chamber, the throttle element ( 142 d) reduces the cross section of the throttled fluid connection ( 142 c). 12. Train limiting device according to claim 11, characterized in that the throttled fluid connection ( 142 c) is associated with a throttle element ( 142 d) in each of the two fluid chambers ( 144 I, 144 II) connected by it. 13. Train limiting device according to one of claims 11 and 12, characterized in that the throttle element ( 142 d) is formed by an elastic plate which, contrary to its inherent elasticity, is adjustable by the pressure in the associated fluid chamber ( 144 I, 144 II). 14. Train limiting device according to one of claims 3-13, characterized in that the braking device ( 38 ) is a direction liquid brake. 15. Train limiting device according to one of claims 1-14, characterized in that the center of gravity of the masses of the braking device ( 38 ) which can be moved with the flap ( 32 ) coincides at least approximately with the pivot axis ( 30 ) of the braking device. 16. Train limiting device according to one of claims 4-15, characterized in that the rotor ( 42 ) and the stator ( 40 ) form a preassembled structural unit which can be connected to the train limiting device ( 24 ). 17. Train limiting device according to claim 16, characterized in that the rotor ( 42 ) by a first connector ( 48 ) on a pivot shaft ( 30 ) of the flap ( 32 ) can be plugged in and at the same time a torque arm ( 40 c) of the stator ( 40 ) a second plug connection ( 50 ) can be connected to a frame ( 26 ) of the train limiting device ( 24 ).