EP0484624A1 - Thermostatic valve for controlling the temperature of the cooling liquid of an internal combustion engine - Google Patents

Abstract

The invention proposes a thermostatic valve (10) for controlling the temperature of the cooling liquid of an internal combustion engine, in which an adjustable supporting part (26) is provided as an abutment for the working plunger (14) of a thermostat based on an expanding material which actuates the valve disc (17). The supporting part (26) is arranged coaxially to the working piston (14) and connected to the latter and is acted upon in the opposite direction to the valve closing direction by means of a spring (35) and pressed into its initial position. The supporting part (26) is adjustable counter to the action of the spring (35) by means of an actuating member (36), in particular a thermostatic working element (37), this working element (37) being electrically heatable. By this means, the working range of the thermostatic valve (10) can be adjusted, for example to a higher opening temperature (winter operation). If the heating fails, the thermostatic valve (10) is adjusted automatically to the other working position by the spring (35) acting on the supporting part (26), resulting, for example, in a lower opening temperature. <IMAGE>

Description

The invention relates to a thermostatic valve for regulating the temperature of the cooling liquid of an internal combustion engine of the type mentioned in the preamble of claim 1.

In a known thermostatic valve of this type (DE-OS 37 05 232), the abutment on which the working piston is supported is part of a coaxial temperature-dependent working element which, for example, can be heated electrically. The arrangement is such that the piston of this actuator guided out of the housing forms the abutment for the working piston of the working element of the thermostatic valve. When the circuit is closed, to which the heating element of the heatable, temperature-dependent working element for adjusting the abutment is connected, the piston is pushed out of the housing axially, which results in a displacement of the working piston of the working element of the thermostatic valve. Heating with pushing out the piston causes the working piston to act in the sense of a shift to a lower opening temperature of the thermostatic valve, for example an adjustment to so-called summer operation. This has the disadvantage that For example, in the event of a power failure in the heating circuit's supply circuit, the heating fails and then the thermostatic valve is automatically moved out of this work area into another work area in which the valve only opens at a higher temperature and which corresponds, for example, to so-called winter operation. Here, the information summer operation and winter operation alone are used for better understanding, without the respective working area being thereby fixed to any temperature. If the thermostatic valve is automatically set to a working position in which the valve only opens at a higher temperature in the event of a power failure of the heating, this can lead to increased stress or even damage to the internal combustion engine, for example if the internal combustion engine is operated at full load if there are higher outside temperatures or the like

The invention has for its object to provide a thermostatic valve of the type mentioned in such a way that it is ensured in a simple and cost-saving manner that the thermostatic valve is automatically adjusted in the event of malfunctions with respect to the abutment adjustment in the starting position assigned to the lower working temperature.

The object is achieved according to the invention in a thermostatic valve of the type mentioned in the preamble of claim 1 by the features in the characterizing part of claim 1. The fact that the supporting part is arranged coaxially to the working piston and is connected to the latter and acts in the opposite direction to the valve closing direction by means of a spring and is thereby pressed into an initial position, guarantees an opposite operating mode. In the event of a malfunction of the element causing the adjustment of the support part, the support part and above the working piston of the working element of the thermostatic valve is automatically pressed into the starting position by the spring, which the corresponds to the lower opening temperature of the thermostatic valve, e.g. summer operation. This ensures that in the event of any malfunctions of the element causing the adjustment of the support part, the thermostatic valve is always brought to the starting position assigned to the lower working temperature, thereby avoiding an undesirable higher load or even damage to the internal combustion engine.

Advantageous further features of the invention and refinements are contained in claims 2-25.

Further details and advantages of the invention result from the following description.

The full wording of the claims is not reproduced above solely to avoid unnecessary repetition, but instead is referred to only by mentioning the claim numbers, whereby, however, all of these claim features are to be regarded as being explicitly disclosed at this point and essential to the invention. All of the features mentioned in the above and the following description, as well as the features that can only be inferred from the drawing, are further components of the invention, even if they are not particularly emphasized and in particular are not mentioned in the claims.

The invention is explained below with reference to an embodiment shown in the drawing. The drawing shows a schematic axial longitudinal section of a thermostatic valve, and to the left of the longitudinal central axis in a setting with a low opening temperature and to the right of the longitudinal central axis in a setting with a higher opening temperature.

The thermostatic valve 10 shown in the drawing is e.g. Similar to that according to DE-OS 33 15 308 or 37 05 232 and is used to regulate the temperature of the cooling liquid of an internal combustion engine, not shown, in particular a motor vehicle engine. The thermostatic valve 10 regulates the coolant flow from the internal combustion engine (not shown further) through a bypass and / or through a heat exchanger (not shown) back to the internal combustion engine.

The thermostatic valve 10 has a valve housing 11 which has a connecting piece 12, via which the coolant can be guided to the heat exchanger. In the valve housing 11, a thermostatic working element 13 is arranged, which has a working piston 14 and a housing 15, in which there is in a known manner an expansion material which can expand when heated and can push out the working piston 14 relative to the housing 15. When it cools down, the expansion material reduces its volume. The working piston 14 is then moved under the action of a valve spring 16 relative to the housing 15 back into the starting position, i.e. pressed into the housing 15.

On the housing 15 of the working element 13, a valve plate 17 is fastened, which is pressed on, crimped or fixed in some other way. The valve plate 17 forms the valve closure member of the thermostatic valve 10. Its outer edge is assigned, for example, a frusto-conical valve seat 18 in the valve housing 11. The valve spring 16 is axially supported at one end by means of a bracket 19 or the like, which in turn is held in arms 20 of the valve housing 11 depending on recesses 20. The other end of the valve spring 16 is supported on the valve plate 17 and strives to press the valve plate 17 in the valve closing direction according to arrow 22 and against the valve seat 18. The drawing shows this condition. That from the Valve plate 17 and the associated valve seat 18 closes or opens the connection between an inlet, not shown, which can be provided, for example, in the area of the arms 21 and in a housing there, and the connecting piece 12 leading to the heat exchanger, in particular the cooler.

Another valve plate 23 is slidably arranged on the housing 15 and is supported on the housing 15 by means of a spring 24. The valve plate 23 is used in a known manner to control a bypass channel, not shown, contained in a connection housing and thus the direct return of the coolant back to the engine.

The working piston 14 of the thermostatic valve 10 is axially supported on an abutment, which is generally designated 25. The drawing shows the thermostatic valve in the starting position when the internal combustion engine is cold. If the internal combustion engine is started, the working element 13 is acted upon by the coolant coming from the engine, which is first led into the bypass channel (not shown) at low temperature and with the valve plate 23 open, while the coolant does not get into the connecting piece 12 due to the closed valve plate 17 can. With increasing heating of the cooling liquid, the expansion material in the housing 15 expands. When a temperature determined by the design of the expansion material is reached, the working piston 14 is extended over a specific working range according to a specific characteristic which is dependent on the expansion material. Since the working piston 14 is axially supported on the abutment 25, this results in a relative displacement of the housing 15 against the arrow 22 and the valve closing direction against the action of the valve spring 16. The housing 15 is initially moved axially so that both the valve plate 17 and the valve plate 23 of the bypass valve are now over a certain temperature range are open. In the event of a further increase in the temperature, by further pushing out the housing 15 in the opposite direction to the arrow 22, the bypass valve is closed via the valve plate 23, while the other valve 17, 18 is now fully open.

In this mode of operation, the thermostatic valve 10, in particular the thermostatic working element 13, is set to a temperature range in which the working piston 14 is moved out of the housing 15 with a linear movement. This temperature range is determined by the choice of the expansion material and other parameters.

The abutment 25 is axially adjustable, whereby the working range of the thermostatic valve 10 can be changed by an intervention from the outside.

In the drawing, another axial position of the abutment 25 and thus another working area is shown to the right of the longitudinal central axis, which e.g. corresponds to the winter operation of an internal combustion engine, in particular a motor vehicle engine, in which the valve 17, 18 only opens at a higher temperature than is the case when the work area is set to the left of the longitudinal central axis.

The abutment 25 has an axially adjustable support part 26. The support part 26 has a plunger 28 axially guided in a bore 27 in the valve housing 11 with an end-side ring part 29 into which the free end of the working piston 14 engages. Part of the support member 26 is also an approximately V-shaped or U-shaped bracket 30, the opening of which is arranged on the side facing away from the working piston 14, that is to say in the drawing above. The bracket 30 has, for example, two diametrically extending arms 31 and 32 which have a receptacle 33 in the region of the facing end of the plunger 28, in which the plunger 28 in the pulling and pushing directions is firmly accepted. The support member 26 is therefore firmly connected to the working piston 14 in the pulling and pushing directions. Because of the housing part 34, in which the bore 27 leading the plunger 28 is contained, good and coaxial guidance to the working piston 14 is thereby ensured.

The support member 26 is arranged coaxially to the working piston 14 and connected to the latter. The support member 26 is urged by means of a spring 35, which is designed here as a cylindrical helical spring, in the opposite direction to the valve closing direction according to arrow 22 and pressed into the starting position, which is shown in the drawing on the left of the longitudinal central axis. The spring 35 has a greater spring stiffness than the valve spring 16, so that when the thermostatic working element 13 responds and the housing 15 moves relative to the supported working piston 14, the valve spring 16 is compressed, while the axial position of the abutment 25, in particular the supporting part 26, remains unchanged .

The support member 26 is adjustable by means of an actuator 36 against the action of its spring 35. The actuator 36 can be designed in various ways as an externally controllable element. In the exemplary embodiment shown, the actuator 36 is designed in a particularly advantageous manner as a temperature-dependent working element 37 similar to the thermostatic working element 13. The actuator 36 is designed in particular as an expansion element which contains expansion material in a housing 38, into which a piston 39 is immersed and which is led out of the housing. The temperature-dependent working element 37 can be heated. For heating, for example, an electric heating element 40 is used, which here consists of a PTC element in a known manner.

This actuator 36 designed in this way, in particular temperature-dependent working element 37, is arranged coaxially with the working piston 14. It is located on the axial side adjacent to the working piston 14. The supporting part 26 is coupled to the actuator 36, in particular the working element 37, in such a way that an axial actuating force directed in the valve closing direction according to arrow 22 results in an axial adjustment of the supporting part 26 against the action of the spring 35 acting thereon, e.g. from the starting position shown on the left of the longitudinal central axis to the other position shown on the right of the longitudinal central axis, in which the abutment 25 has been displaced axially further upwards, which e.g. corresponds to a higher opening temperature in the working element 13. If the described actuating force drops, this results in an axial adjustment of the support part 26 and the actuating member 36, in particular thermostatic working element 37, which is carried away by the action of the spring 35 and thereby in the opposite direction to the valve closing direction according to arrow 22.

On the support part 26, namely the end of the arms 31, 32, which face away from the plunger 28, a ring 41 is fastened, which the housing 38 of the actuator 36 arranged coaxially to the working piston 14, in particular temperature-dependent working elements 37, e.g. includes with play and by means of the spring 35 in the opposite direction to the valve closing direction according to arrow 22 to a driver 42 of the actuator 36, in particular of the working element 37, is pressed. The driver 42 is here e.g. from an annular shoulder of the housing 38, on which the ring 41 bears positively so that it cannot slide further down in the drawing. In another embodiment, not shown, the driver 42 consists of a radial projection or the like.

The spring 35, which is supported at one end on the ring 41 and thus on the support part 26, is at its other end facing away from the support part 26 on a housing part 43 axially supported. This housing part 43 is designed, for example, as a rotationally symmetrical cup which is attached to the valve housing 11 with its end which is approximately adjacent to the support part 26. This end is formed here, for example, as a ring edge 44. The housing part 43 is held at this end, for example by means of a flange connection on the valve housing 11. The attachment here is carried out by a flanged edge 45 of the valve housing 11 which overlaps the ring edge 44. The upper bottom part of the housing part 43 in the drawing contains a central opening 46 through which the end of the actuator 36, in particular temperature-dependent working element 37, extends outwards.

As can be seen, the spring 35 and / or the housing part 43 surrounds the actuator 36, in particular the temperature-dependent working element 37, with a radial distance, these parts being arranged at least essentially coaxially and concentrically with one another. The actuator 36, in particular temperature-dependent working element 37, is arranged so that its piston 39 is directed towards the working piston 14. The piston 39 is axially supported on the valve housing 11, in particular on the housing part 34 located approximately in the middle. If the working range is to be adjusted from that on the left of the longitudinal central axis to that on the right of the longitudinal central axis, the circuit feeding the heating element 40 is closed. The electric heating element 40 heats up, so that the expansion material contained in the housing 38 expands. This results in a relative displacement between the housing 38 and the piston 39 in the axial direction. Since the piston 39 is supported on the end of the valve housing 11, the housing 38 can be moved relative to the piston 39 in the valve closing direction according to arrow 22, taking the supporting part 26 together with the working piston 14, into the position on the right of the longitudinal central axis, and thereby the working range of the thermostatic valve 10 such higher working temperature adjustable.

To support the piston 39, e.g. reversed U-shaped bridge member 47 is provided, which is designed similar to a fork. The bridge member 47 has an upper web part 48, to which two spaced, approximately parallel legs extend downward, of which only one leg 49 can be seen in the drawing due to the sectional view. Between the spaced legs 49 of the bridge member 47, the two bracket arms 31 and 32 of the bracket 30 engage with play and move through, so that the axial adjustment movement of the support member 26 is not hindered thereby. The bridge member 47 is held and supported at the end of its legs 49 on the valve housing 11, specifically on the housing part 34. With the web part 48 running transversely between the legs 49, the bridge member 47 forms an axial abutment for the piston 39 of the actuator 36, in particular temperature-dependent working elements 37. The web part 48 contains e.g. a bore 50 in which the end of the piston 39 is received.

If, starting from the working position shown in the drawing on the right of the longitudinal central axis and achieved by heating the temperature-dependent working element 37, a different working position, for example the working position shown on the left of the longitudinal central axis, is to be reached for the thermostatic valve 10, the circuit feeding the electrical heating element 40 is opened. The heating and thus heating of the working element 37 is thus interrupted, so that the working element 37 can cool down again. The cooling results in a reduction in the volume of the expansion material in the housing 38. As a result, the spring 35 can adjust the support part 26 and with this the housing 38 relative to the axially supported piston 39 in the axial direction in the opposite direction to the arrow 22 into the other position shown on the left of the longitudinal central axis. In this position, for example, the temperature-dependent working element 13 is at a lower opening temperature set so that it opens at a lower temperature of the coolant in the manner described above.

The thermostatic valve 10 is simple, inexpensive and can be assembled using simple means and in a modular manner, since e.g. the thermostatic working elements 13 and 37 can be identical or at least functionally identical. Above all, the thermostatic valve has the advantage that, under the action of the spring 35, it then automatically returns to the starting position shown to the left of the longitudinal central axis and thus to a lower opening temperature, e.g. the electrical supply to the heating element 40 is interrupted by a malfunction or the like. In these cases, any impairment or even damage to the internal combustion engine is reliable and is ruled out in a simple and inexpensive manner.

Claims (25)

Thermostatic valve for regulating the temperature of the cooling liquid of an internal combustion engine, in particular a motor vehicle engine, which regulates the coolant flow from the internal combustion engine through a bypass and / or through a heat exchanger back to the internal combustion engine, a housing (15) containing an expansion material being provided by a valve spring (16) is acted on in the valve closing direction, carries at least one valve plate (17) and contains a working piston (14) which extends when heated relative to the housing (15) and effects the stroke of the valve plate (17) and which has an adjustable support part as an abutment (25) (26) is assigned, characterized in that the support part (26) is arranged coaxially to the working piston (14) and connected to the latter and that the support part (26) is acted upon by a spring (35) in the opposite direction to the valve closing direction (arrow 22) and in a starting position is pressed. Thermostatic valve according to claim 1, characterized in that the spring stiffness of the spring (35) is greater than that of the valve spring (16). Thermostatic valve according to claim 1 or 2, characterized in that the supporting part (26) has an approximately V-shaped or approximately U-shaped bracket (30), the opening of which is arranged on the side facing away from the working piston (14). Thermostatic valve according to claim 3, characterized in that the bracket (30) with its part lying approximately in the region of the longitudinal central axis of the working piston (14) is connected directly or indirectly, for example via a tappet (28), to the facing end of the working piston (14) is. Thermostatic valve according to one of claims 1 to 4, characterized in that the supporting part (26) is firmly connected to the working piston (14) in the pulling and pushing directions. Thermostatic valve according to one of claims 1-5, characterized in that the support part (26) is adjustable by means of an actuator (36) against the action of the spring (35). Thermostatic valve according to one of claims 1-6, characterized in that the actuator (36) is designed as a temperature-dependent working element (37). Thermostatic valve according to one of claims 1 to 7, characterized in that the control element (36) is designed as a heatable, in particular electrically heatable, temperature-dependent working element (37). Thermostatic valve according to one of claims 1-8, characterized in that the actuator (36) is designed as an expansion element which has an expansion material contained in a housing (38) into which a piston (39) is immersed and which emerges from the housing (38 ) is brought out. Thermostatic valve according to one of claims 1-9, characterized in that the actuator (36) is arranged coaxially with the working piston (14). Thermostatic valve according to one of claims 1-10, characterized in that the actuator (36) is arranged on the axial side adjacent to the working piston (14). Thermostatic valve according to one of claims 1 to 11, characterized in that the supporting part (26) is coupled to the actuator (36), in particular thermostatic working element (37), in such a way that an axial actuating force directed in the valve closing direction (arrow 22) adjusts the axis of the support part (26) against the action of the spring (35) acting on it. Thermostatic valve according to claim 12, characterized in that a drop in the actuating force results in an axial adjustment of the support part (26) and the actuating member (36) entrained therefrom, in particular temperature-dependent working elements (37), under the action of the spring (35) in the opposite direction to the valve closing direction (arrow 22). Thermostatic valve according to one of claims 1-13, characterized in that a ring (41) is fastened to the support part (26), said ring (41) of the actuator (36), in particular temperature-dependent working elements (37) arranged coaxially to the working piston (14) ), and is pressed by means of the spring (35) in the opposite direction to the valve closing direction (arrow 22) to a driver (42), for example a radial projection, an annular shoulder or the like., of the actuator (36), in particular temperature-dependent working elements (37) . Thermostatic valve according to one of claims 1-14, characterized in that the spring (35) is designed as a cylindrical helical spring. Thermostatic valve according to one of claims 1-15, characterized in that the spring (35) is axially supported on a housing part (43) with the end facing away from the supporting part (26). Thermostatic valve according to claim 16, characterized in that the housing part (43) is designed as a bracket or as a cup, which is attached to the valve housing (11) with its end adjacent to the support part (26). Thermostatic valve according to claim 17, characterized in that the end of the housing part (43) is held on the valve housing (11) by means of a flanged connection (44, 45), for example by means of a flanged edge (45). Thermostatic valve according to one of claims 1-18, characterized in that the spring (35) and / or the housing part (43) surrounds the actuator (36), in particular the temperature-dependent working element (37), with a radial distance. Thermostatic valve according to one of claims 1-19, characterized in that the actuator (36), in particular temperature-dependent working element (37), is arranged such that its piston (39) is directed towards the working piston (14). Thermostatic valve according to claim 20, characterized in that the piston (39) of the temperature-dependent working element (37) is axially supported on the valve housing (11, 34) and when the temperature-dependent working element (37) responds, its housing (38) relative to the piston (39) in the valve closing direction (arrow 22) with the support part (26), together with the working piston (14), and thereby the valve working area can be adjusted to a higher opening temperature. Thermostatic valve according to one of claims 6 - 21, characterized in that an approximately inverted U-shaped bridge member (47) is provided for supporting the piston (39), between the spaced legs (49) the bow arms (31, 32) of the bow-shaped Grip the support part (26) so that it can move. Thermostatic valve according to claim 22, characterized in that the bridge member (47) is firmly held and supported by the end of its legs (49) on the valve housing (11, 34). Thermostatic valve according to claim 22 or 23, characterized in that the bridge member (47) with its web part (48) extending transversely between the legs (49) forms an axial abutment for the piston (39) of the temperature-dependent working element (37). Thermostatic valve according to claim 24, characterized in that the piston (39) is received in a bore (50) of the web part (48).

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