DE10257570A1 - Float valve insert for air filter housing, e.g. for automobile IC engine, has valve shaft provided with seals at both ends and magnetizable or permanent magnet retaining element - Google Patents

Abstract

The float valve insert (10) has 2 valve seats (8,6), a valve shaft (12) provided with corresponding seal sections at either end, a drive chamber (11) in the vicinity of the valve shaft and a retaining component, providing a retaining force for the float valve insert, adjacent the first seal section. The retaining component can be provided by a magnetizable metal element or by a permanent magnet (9). An Independent claim for a housing group for an air intake of an IC engine is also included.

Description

The invention relates to a float valve for a Air filter housing.

In the DE 197 56 247 A1 discloses an air filter housing that must be installed on an internal combustion engine at an angle to the horizontal. This ensures that water that has penetrated the air filter can run onto the outside of the air filter housing and does not get into the combustion chamber of the engine. This device has not proven itself when it comes to preventing water from entering the engine compartment. In particular, the problem arises here that air mass meters provided in the area of the engine compartment are impaired or even completely destroyed by the penetrating water.

It is an object of the invention To provide an intake system in which there is an air mass meter reliable operated.

This task is the subject of independent Expectations solved. Advantageous further developments result from the respective dependent claims.

The invention provides a housing assembly which can be operated in particular on an internal combustion engine, which has an air duct. A drainage chamber is located in the air duct Connection in which a float valve according to the invention is arranged is. The float valve has a first valve seat and a second valve seat as well as a float valve insert. The float valve insert is structured into a valve stem on which a first sealing section and a second sealing section is arranged. Also in the area of the valve stem a buoyancy chamber is provided. In addition, according to the invention is in the area of the first sealing section, a holding component for generating a Holding force arranged in the float valve insert.

Closes according to the invention in a first operating state the first sealing section the first valve seat. In a second The second sealing section becomes operational through the second Valve seat closed.

The holding component is magnetic actable metal part or designed as a permanent magnet, so that the float valve insert over that Holding component in the float valve are subjected to a force can. The first valve seat is advantageously in one first operating state closed by the first sealing section, and because of the effect of the holding device. In a second The second valve seat is in the operating state by the second sealing section closed, in particular through the cooperation of Buoyancy chamber with the water in the dewatering chamber as well as by negative pressure in the air duct.

Alternatively, or in addition the sealing surface of the second sealing section is also larger than the sealing surface of the first sealing section executed his. Under "sealing surface" here is in particular the from the projection of the sealing edge in the direction of movement of the float valve insert enclosed area Roger that. With this configuration, the air pressure in the intake tract in connection with the water in the air filter housing also a drainage according to the invention cause if the device is adjusted accordingly.

According to the invention, it is possible to hold the holding component on Float valve insert, for example by means of an electrical coil apply. This results in a reliable effect of the float assembly according to the invention.

The drainage chamber and the float valve insert are advantageously designed so that the float valve insert in essentially jumps from the first operating state to the second Operating state changes, so that a non-linear path-time characteristic is achieved.

Through the training according to the invention a float valve insert and the housing assembly is ensured that the air duct always just over provided routes are supplied with air. It can still be done the drainage chamber Water to the outside the housing assembly emerge, this preferably through the second valve seat through down. So it gathers in a first Operating state water in the drainage chamber on, namely until the water level in the drainage chamber is so high that the float valve insert due to the buoyancy of the Buoyancy chamber is lifted from the second valve seat. By the thus released valve seat runs the water from the drainage chamber to the outside the housing assembly from. Due to the sinking water level in the drainage chamber dissolves the float valve insert from the first valve seat and goes into the second operating state back, in which the second valve seat is closed by the second sealing section is. Both in the first operating state and in the second operating state can no foreign air through the first valve seat or through the second valve seat in the interior of the housing assembly and in the air duct reach. This will ensure the safe functioning of the internal combustion engine provided, both the inflow of external air as well the penetration of water into the air duct is avoided.

In a development of the invention, the first sealing section or the second sealing section cut open a heel area with a flexible sealing component arranged thereon, which can be designed in particular as an O-ring. This means that a reliable seal can be achieved both against outside air entry and against unwanted water exit.

Finally, it can still be provided be the valve stem in the area of the first sealing section or in the area of the second sealing section with an overlap equip each sealing section extending guide section. With such a guide section can the float valve insert in a particularly reliable manner guided in the float valve become what favors its function.

According to the invention, the float valve into a divided volume of the lower part of the damper filter an internal combustion engine installed. In this closed volume there is a large one at the top Hole and a small hole below. The float of the float valve insert is designed so that it can move vertically in the holes and a sealing surface at both ends has. The movement of the float valve insert must be erratic done so that there are only two possible Positions of the float valve insert there. Such a jump function can be implemented at the bottom of the float valve and the lower part of the damper filter a pair of magnets arranged. The magnetic forces and the size of the lower one sealing surface are now designed so that the swimmer will only Water level from the magnet releases and then abruptly pressed against the upper sealing surface. The top sealing surface should be so big that the maximum negative pressure can carry approx. 80% of the float weight, to get a jump function in this direction of movement.

In the invention, the The advantage of simple and safe installation, being a solution for all engine variants and vehicle variants possible is. The invention works regardless of the package situation.

It is also conceivable to use an exhaust hose a check valve to be provided at the end of the hose, which extends from the lower part of the air filter extends down to a subframe where it is attached. The forming water column acts against the negative pressure inside the air filter housing and allows so the water drain. The hose is in the vehicle because of the package situation as well as for assembly reasons to be viewed critically. The solution according to the invention has the opposite The advantage that a hose is no longer required. For the rest is the training according to the invention insensitive to dirt, which is a disadvantage with the check valve. About that in addition, no hose is required in the invention. The Invention is cost neutral with regard to the removal of Water, whereby a significant reduction in the size of the valve is achieved can be.

The invention is in the drawing based on an embodiment illustrated in more detail.

1 shows a cross section through an air filter housing according to the invention,

2 shows a further cross section through the air filter housing 1 and

3 shows a path diagram for a float valve insert, according to the air filter housing 1 and 2 is housed.

1 and 2 show cross sections through an air filter housing 1 , The air filter housing 1 has a basic body 2 made of plastic, in which a filter element, not shown in this view, is inserted. The basic body 2 is closed by a housing cover, also not shown in this view. The basic body 2 is on an intake tract 3 an internal combustion engine not shown in this view. The intake tract 3 air is supplied due to the suction effect of the internal combustion engine, which is filtered by the filter element of dirt.

In the basic body 2 is a drainage chamber 4 trained the top of a baffle 5 is limited. In the baffle 5 is an upper valve seat 6 provided as a tapered through hole. The drainage chamber 4 is down through a drainage chamber pot 7 limited, which tapers towards the bottom. At the bottom is the drainage chamber pot 7 with a lower valve seat 8th provided, which is designed as a tapered downward through hole. Around the lower valve seat 8th there is a ring-shaped permanent magnet around it 9 arranged. The lower valve seat 8th has a smaller sealing surface than the upper valve seat 6 ,

Inside the drainage chamber 4 is a float valve insert 10 arranged. The float valve insert 10 is designed as an injection molded part with a waterproof buoyancy chamber inside 11 having. The float valve insert is around an axis of symmetry 12 rotationally symmetrical, with a first guide section at its upper end 13 and at its lower end a second guide section 14 is provided. The first leadership section 13 and the second guide section 14 have three guide section wings pointing away from each other 15 with which the float valve insert 10 in the upper valve seat 6 and in the lower valve seat 8th is led. Thus, the float valve insert 10 along the axis of symmetry 12 inside the drainage chamber 4 be moved. At the bottom of the buoyancy chamber 11 is a magnetic plate 19 intended.

The float valve insert 10 spreads to a swimmer section in its upper half 16 who at the in 1 top side on the outside a circumferential seal ring shoulder with an O-ring inserted therein 17 having. The o-ring 17 is designed in terms of its diameter so that it is the upper valve seat 6 seals when the float valve insert 10 is moved to its upper setting.

In 1 is a water level 18 marked the current state of the air filter housing 1 characterized.

The air filter housing behaves during operation 1 as follows. In the air filter housing 1 and in its main body 2 Incoming air flowing in first hits the baffle 5 where it releases the water it contains. This water runs through the upper valve seat 6 through to the drainage chamber 4 , From the drainage chamber 4 this water cannot drain because the lower valve seat 8th is through the bottom of the float valve insert 10 tightly closed. The float valve insert 10 through the interaction of the permanent magnet 5 and the magnetic plate 19 firmly in the lower valve seat 8th held.

The water level rises 18 above the in 1 bounded by H '', then overcomes from the float section 16 and the buoyancy chamber 11 generated buoyancy the force between the permanent magnet 9 and the magnetic plate 19 , This causes the float valve insert to move 10 up until the O-ring 17 at the upper valve seat 6 is applied and seals it.

The float valve insert is in this state 10 additionally due to the negative pressure in the upper valve seat 6 held by the intake tract 3 is produced.

In this state, the water from the drainage chamber begins 4 down through the lower valve seat 8th drain, on the outside of the air filter housing 1 ,

As soon as the water level 18 has dropped below the height h ', the vacuum passes through the intake tract 3 no longer out to the float valve insert 10 in the upper valve seat 6 to keep. The float valve insert 10 then moves back down into the in 1 position shown.

3 illustrates this sequence of movements of the float valve insert 10 , the lower position according to 1 is labeled "1" and the upper position of the float valve insert 10 in which the O-ring 17 at the upper valve seat 6 is present, is marked with "2". These states are plotted on the vertical axis. The water level is in the horizontal axis 18 applied. The diagram in 3 illustrates the dependence of the operating states of the float valve insert 10 depending on the water level 18 ,

In a further exemplary embodiment, not shown here, the invention is applied to the float insert without the use of a special holding component for generating a holding force. This embodiment agrees with that in FIGS 1 to 3 shown embodiment almost identical. Only the magnetic plate 19 and the permanent magnet 9 are omitted. Holding the float insert 10 at the upper valve seat 6 occurs due to negative pressure in the intake tract 3 and due to the buoyancy of the buoyancy chamber 11 and the float section 16 , The float insert 10 decreases in the absence of negative pressure in the intake tract 10 due to its own weight down and closes the lower valve seat 8th , The function in this embodiment is coordinated by varying the distance between the valve seats and the float insert 10 in terms of weight, shape, volume and size of the pressure areas in the valve seats.

Claims (9)

Float valve insert ( 10 ) especially for an air filter housing ( 1 ), which has the following features: - a valve stem ( 12 ), - one at a first end of the valve stem ( 12 ) arranged first sealing section, - a second sealing section arranged at the second end opposite the first end ( 17 ), - in the area of the valve stem ( 12 ) is a buoyancy chamber ( 11 ) is arranged, - in the area of the first sealing section there is a holding component ( 19 ) to generate a holding force on the float valve insert ( 10 ) arranged. Float valve insert ( 10 ) especially for an air filter housing ( 1 ), which has the following features: - a valve stem ( 12 ), - one at a first end of the valve stem ( 12 ) arranged first sealing section, - a second sealing section arranged at the second end opposite the first end ( 17 ), - in the area of the valve stem there is a buoyancy chamber ( 11 ) arranged, - the sealing surface of the second sealing section ( 17 ) is larger than the sealing surface of the first sealing section. Float valve insert according to claim 1 or claim 2, characterized in that the holding component as a magnetically loadable metal part or as a permanent magnet ( 9 ) is trained. Float valve insert according to one of the preceding claims, characterized in that the first sealing section and / or the second sealing section has a heel area with a flexible sealing component arranged thereon ( 17 ) having. Float valve insert according to one of the preceding claims, characterized in that that the valve stem in the area of the first sealing section and / or in the area of the second sealing section ( 17 ) a guide section extending beyond the respective sealing section ( 13 ; 14 ) having. Float valve, which has the following features: - a first valve seat ( 8th ), - a second valve seat ( 6 ), - a float valve insert ( 10 ) according to one of claims 1 to 4, wherein the first sealing portion in the region of the first valve seat ( 8th ) is arranged and wherein the second sealing section ( 17 ) in the area of the second valve seat ( 6 ) is arranged, - the holding component ( 19 ) of the float valve insert is part of a magnetic holding device ( 9 . 19 ). Housing assembly ( 1 ) especially for an internal combustion engine with an air duct ( 3 ) and with one with the air duct ( 3 ) related drainage chamber ( 4 ), in which a float valve according to claim 5 is arranged so that in a first operating state ("1"), the first sealing section the first valve seat ( 8th ) closes and that in a second operating state the second sealing section ( 17 ) the second valve seat ( 6 ) closes. Housing assembly according to claim 7, characterized in that the drainage chamber ( 4 ) and float valve insert ( 10 ) are designed so that in the first operating state ("1") the first sealing section engages the first valve seat ( 8th ) by the action of the holding device ( 9 . 19 ) closes and that in the second operating state the second sealing section ( 17 ) the second valve seat ( 6 ) through the interaction of the buoyancy chamber ( 16 . 11 ) with in the drainage chamber ( 4 ) standing water ( 18 ) closes. Housing assembly according to claim 8, characterized in that the drainage chamber ( 4 ) and float valve insert ( 10 ) are designed so that the float valve insert ( 10 ) essentially jumps from the first operating state ("1") to the second operating state and back.