DE8904436U1 - Thermostatic valve, especially for internal combustion engines - Google Patents

Description

Patent Attorney "Müifeergersfr.66 Authorized representative at Dipl.-lng. Volkhard Kratztch D-7300 E-Mlingen European Patent Office T«Max (0711131 32 48 European Patent Attorney Telephone Stuttgart (0711) 317000 Deutsche Bank Esslingen 210906 cable «krapatent» esslinganneckar Postgiroamt Stuttgart 10004-701

Gustav Wahler GmbH & Co

6 April 1989

7300 Esslingen

Lawyer sect 4684

Thermostatic valve, especially for Br e &eegr;&eegr; kraftma s c h i &eegr; *? r·.

The invention relates to a thermostatic valve, in particular for internal combustion engines, of the type defined in the preamble of claim 1.

Thermostat valves of this type have already been proposed, which are provided with an additional pressure relief valve in the area of the second valve element (bypass valve), the valve element of which can open into the bypass channel against the action of a valve spring. In this way, any excess pressure occurring in the cooling system can be reduced by automatically opening the pressure relief valve when the set opening pressure is reached, and the system can be protected from damage caused by this. This can be necessary, for example, if, when the main valve of the thermostat valve is open, the amount of coolant supplied by the internal combustion engine, passing through and reaching the heat exchanger, is greater than the capacity of the heat exchanger, so that an excess pressure can then build up in the system, which can be harmful, especially for the heat exchanger, which is not designed for this. By opening the pressure relief valve, a

such excess pressure must be relieved and the system protected from possible damage.

has proposed that the valve spring which acts on the valve member of the pressure relief valve in the closed position should be supported on such an abutment which is part of the housing of the thermostatic^»· working element and
can thus move together with it relative to the second valve element, e.g. in the event of overstroke. Then a

Movement causes the distance of the abutment from the
valve member held in the closed position, which
This results in a change in the set opening pressure of the pressure relief valve. The further the housing of the thermostatic working element moves relative to the housing-side valve seat of the main valve in the event of overstroke,
shifts, the more the valve spring of the
Valve element of the pressure relief valve, whereby the set opening pressure of the pressure relief valve
towards smaller opening pressures. This

is undesirable.

The invention is based on the object of providing a thermostatic valve of the type mentioned in the preamble of claim 1
to be designed in such a way that the set opening pressure of the overpressure value cannot change due to relative displacement of the thermostatic actuator, in particular its housing.

This task is carried out by a thermostatic valve1 according to the
The genus of claim 1 is accordingly solved by the features in the characterizing part of claim 1.

In this way, it is possible that even with relative movements of the thermostatic working element, in particular of its housing, especially in the overstroke area, the position of the abutment for the valve spring of the

The valve element of the pressure relief valve is not changed and thus the set opening pressure of the pressure relief valve remains unchanged. In all, the thermostat valve is extremely simple and cost-effective in terms of this design , whereby the desired small dimensions of the thermostat valve can be retained.

A particularly advantageous embodiment results from claim 2. According to line ¹ , the abutment of the valve spring of the pressure relief valve is firmly attached to the second valve member (bypass valve plate). Further advantageous embodiments result from claims 3 - 9.

Further details and advantages of the invention will become apparent from the following description.

The full wording of the claims is not reproduced above alto avoid unnecessary repetition, but instead merely by

*O Reference is made to the claim numbers, whereby all of these claim features are to be regarded as expressly disclosed at this point and as essential to the invention. In this context, all features mentioned in the above and following description as well as the features that can be taken from the drawing alone are further components of the invention, even if they are not particularly emphasized and in particular not mentioned in the claims.

The invention is explained in more detail below using an embodiment shown in the drawings.

Fig. 1 is a schematic, partially sectioned side view of a thermostatic valve

especially for internal combustion engines,

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*■ Fig. 2 is a schematic, partially sectioned

A side view of detail II in Fig. 1 on a larger scale.

° In Fig. 1 and 2 a thermostat valve 10 is shown, which is used in particular for internal combustion engines and is placed in an arrangement not shown, e.g. between a housing and a housing cover, whereby the housing and the housing cover form a total of three channels, which can be connected to one another via a cavity contained in the housing in which the thermostat valve is to be placed. The thermostat valve 10 is able to control a medium flow, in particular the coolant flow of an internal combustion engine, from an inlet (not shown here in more detail, which is only indicated by arrow 11), to a return according to arrow 12 and/or to a bypass channel according to arrow 13. The inlet according to arrow 11 carries coolant coming from the internal combustion engine, which passes in the direction of arrow 12 to the heat exchanger (not shown), in particular the cooler, and from there in the return flow back to the internal combustion engine. In the position shown in Fig. 1, this passage from the inlet according to arrow 11 is blocked by the thermostat valve 10 to the return flow in the direction of arrow 12. In contrast, a passage from the inlet in the direction of arrow 11 through the thermostat valve 10 in the direction of arrow 13 to the bypass channel is opened, via which the coolant is returned directly to the internal combustion engine, bypassing the heat exchanger, in particular the cooler.

The mode of operation of such a thermostatic valve 10 is known.

The thermostat valve 10 has a thermostatic working element 14 with a housing 15. The housing 15 carries a first valve member 16, which is designed as a valve disk

and is supported on a housing shoulder 17 in the opening direction according to arrow 18. This first, plate-shaped valve member 16 interacts with a valve seat 19, which is also part of the thermostat valve 10. Between, for example, two hanging arms of the thermostat valve housing and the first, plate-shaped valve member 16 there is a return spring 21 which presses the first, plate-shaped valve member 16 and the housing 15 of the thermostatic working element 14 upwards in Fig. 1, the first, plate-shaped valve member 16 interacting with the annular valve seat 19 to close it.

A freely movable/wide valve member 23, which is also designed as a valve plate, is held with a sliding seat on the housing 15 of the thermostatic working element 14 at its lower end 22, which projects beyond the lower end of the arms 20. This second, plate-shaped valve member 23 is ^assigned a valve seat in the usual way in the non-adjusted bypass channel.

*® so that when the second, plate-shaped valve member rests on the valve seat by axial movement in the direction of arrow 13, this bypass channel is closed and thus the passage from the inlet according to arrow 11 to the bypass channel according to arrow 13 is blocked. This is also known for such thermostatic valves 10.

The second valve member 23 is under the action of a return spring 24, which is supported at one end on a housing shoulder 25 of the housing 15 and rests at its other end on the plate-shaped second valve member. The housing 15 has a radially projecting locking ring 26 in the area of the lower end 22, against which the second, plate-shaped valve member 23 is pressed under the action of the return spring 24 and which serves as an axial lock for the second valve member 23.

II· , 'lit· * t

In the area of this second valve member 23, an additional pressure relief valve is arranged, which is generally designated 27 and has a valve member 28 which can open against the action of a valve spring 29 in the direction of arrow 13 and into the bypass channel. The force of the valve spring 29 acting on the valve member 28 is set to a certain desired opening pressure and thus the pressure relief valve 77. The pressure relief valve 27 has the following advantage. In some cases, with

^&khgr;&ugr; when the thermostat valve 10 is used, when the first valve member 16 is open, the amount of cooling water that flows from the inlet according to arrow 11 through the valve 16, 19 in the direction of arrow 12 and from there to the heat exchanger, in particular the cooler, can be so large that the capacity of the heat exchanger, in particular the cooler, is not large enough for this amount of cooling water to prevent the resulting, impermissibly high pressures and thus damage to the heat exchanger. In other words: If the heat exchanger capacity is too low, impermissibly high pressures arise in the heat exchanger in these cases, for which the heat exchanger is not designed and which can therefore cause damage to the heat exchanger. If the cooling water quantity has thus reached an opening pressure set in the area of the pressure relief valve 27, the pressure relief valve 27 opens in this case, so that when the first valve 16, 19 is open, the pressure relief valve 27 now opens into the bypass channel according to arrow 13 despite the second valve member 23 being in the closed position, and thus a partial quantity of the cooling water is discharged in the direction of arrow 13 via the bypass channel, thereby reducing the harmful excess pressure.

Details of the pressure relief valve 27 are explained below. The valve spring 29 acting on the valve member 28 is supported at one end on the valve member 28. The other end 30 of the valve spring 29 is attached to a

* Abutment 31 is supported, whereby this abutment 31 is at least in the valve position in which the second, plate-shaped valve member 23 is closed and thus the invisible bypass channel is blocked, in a constant

° is arranged at a large distance from the second, plate-shaped valve member. This means that, regardless of the current position of the housing 15 of the working element 29, the abutment 31 does not change its position locally, but remains spatially fixed, which means _that the set discharge pressure of the pressure relief valve always remains the same and cannot change.

In an embodiment not shown, the abutment 31 of the valve spring 29 can be arranged in the bypass channel at a distance from the housing-side valve seat associated with the second, plate-shaped valve member 23.

In the embodiment shown, the abutment of the valve spring 29 is attached to the second valve member 23. _The abutment 31 has at least two holding arms 32, 33 arranged at a distance from one another with leg parts 34, 35 projecting transversely therefrom, on which the valve spring 29 rests with its facing end 30 and on which the latter is axially supported, while the opposite end of the valve spring 29 rests on the valve member 28 of the pressure relief valve 27 and acts on it in the closed position according to Fig. 1 and 2.

The at least two holding arms 32, 33 are attached to the second, tetrahedral valve member 23 and protrude downwards from it in Fig. 1 and 2, thus in the direction of the valve member 28 of the pressure relief valve 27.

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Just as the second valve member 23 is designed as a valve plate, the valve member 28 of the pressure relief valve 27 is also designed as a valve plate which, in the closed position of the pressure relief valve 27 shown, rests flatly on the lower side of the second, plate-shaped valve member 23 in Fig. 1 and 2, d = h. on the side facing away from the first, plate-shaped valve member 16. The pressure relief valve 27 is thus designed in a simple manner as a plate valve, at least one valve opening 36 of which is contained in the plate-shaped second valve member 23, which is closed when the pressure relief valve 27 is closed by the fact that the valve member 28 is pressed against this at least one valve opening 36 by the valve spring 29 acting in the closing direction.

The pressure relief valve 27 designed in the manner described is simple, inexpensive, space-saving and reliable. It has the particular advantage that the abutment 31 for the valve spring 29 is independent of the displacement movement of the housing 15 of the thermostatic working element 14, whereby the local position of the abutment 31 no longer changes at least when the second, plate-shaped valve member 73 has moved downwards from the position shown and is seated on the associated valve seat on the housing side and is in the closed position. Even if the housing 15 of the thermostatic working element 14 should then move further in the direction of the arrow 13 relative to this second valve member 23 due to an overstroke movement, this displacement movement has no influence on the setting and behavior of the pressure relief valve 27. The locking ring 26 simply moves further downwards together with the housing 15 in the direction of the arrow 13, whereby it lifts off the second valve member 23 downwards. The valve member 28 is still pushed by the valve spring 28, which is supported with its end 30 on the abutment 31.

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pressed from below against the second valve member 23 and thus held in the closed position. The abutment does not change its position, so that the opening pressure of the pressure relief valve 27 set via the valve spring 29 remains constant, i.e. does not change due to relative displacement of the housing 15. This ensures that the pressure relief valve 27 opens exactly when the set opening pressure is reached, regardless of which overstroke movement the housing 15 of the thermostatic working element 14 has performed.

Claims (1)

Expectations Thermostat valve, in particular for internal combustion engines, which has a thermostatic working element (14) which has a first valve member (16) actuated by the working element (14), interacting with a valve seat (19) and controlling the medium flow, and a first valve member (16) actuated by the working element (14) and freely movable relative thereto in one direction against the action of a return spring (24). I _ _ J- -i 1 _T J-- associated second valve seat of a bypass channel, and with an additional pressure relief valve (27) arranged in the area of the second valve member (23), whose valve member (28) can open into the bypass channel against the action of a valve spring (29), characterized in that the valve spring (29) loading the valve member (28) of the pressure relief valve (27) in the closing direction is supported on an abutment (31) arranged - at least after closing the second valve member (23) - at a constant large distance from the second valve member (23). -2- V. Thermostatic valve according to claim 1, characterized in that the abutment (31) of the valve spring (29) is fixedly attached to the second valve member (23). 3. Thermostat valve according to claim 1 or 2, characterized in that the abutment (31) of the valve spring (29) has at least two holding arms (32, 33) arranged at a distance from one another with legs (34, 35) projecting transversely therefrom, on which the valve spring (29) rests axially and on which the valve spring (29) is supported with its one end (30), while the opposite end of the valve spring (29) engages the valve member (20) of the pressure relief valve (27). 4. Thermostat valve according to claim 3, characterized in that the at least two holding arms (3Z, 331) are attached to the second valve member (23) and protrude from it in the direction of the valve member (26) of the pressure relief valve (27). 5. Thermostat valve according to claim 1, characterized in that the abutment is arranged at a distance from the valve seat assigned to the second valve member (23) in the bypass channel. 6. Thermostat valve according to one of claims 1-5, characterized in that the second valve member (23) is designed as a valve plate. 7. Thermostat valve according to one of claims 1-6, characterized in that the pressure relief valve (27) is designed as a disk valve, at least one valve opening (36) of which is contained in the second valve member (23) and whose valve member (2Θ) -3- *■ under the valve spring (29) acting in the closing direction against which at least one valve opening (36) is pressed while closing it. ^ &THgr;. Thermostat valve according to one of claims 1-7, characterized in that the valve member (2&THgr;) of the pressure relief valve (27) is designed as a valve disk. J-O 9. Thermostatic valve 1 according to one of claims 6 - 8, characterized in that the valve plate of the pressure relief valve (27) in the closed position of the pressure relief valve (27) rests flat against the side of the second valve member (23) which faces away from the first valve member (16).