DE102016005771B4 - Valve device for a motor vehicle and associated motor vehicle - Google Patents

Abstract

Valve device (1) with an inlet channel (2), an outlet channel (3), a throttle (10) with an opening and a locking device (4) for closing the opening, the locking device being adjustable between a locking and an open position, wherein the locking device (4) comprises a locking head (5) and a locking shaft (6) connected to the locking head (5), the valve device (1) having an overpressure control device and a thermostat device, the thermostat device having a thermally reactive expansion element (8), characterized in that the input channel (2) and the output channel (3) are arranged axially to one another and the throttle (10) axially follows the input channel (2), the axially following the throttle (10) and in the blocking position axially on the throttle (10) applied locking device (4) can be moved axially between the locking and open positions both by the overpressure control device through a fluid pressure applied on the input channel side to the locking device (4) closing the throttle (10) and by the thermostat device, the thermally reactive expansion element (8) is arranged in a cavity of the locking shaft (6), is supported on a position-fixed support device (13), which engages in the locking head (5) and guides it, and on an inside of the cavity of the locking shaft (6).

Description

The invention relates to a valve device with an inlet channel, an outlet channel, a throttle with an opening and a locking device for closing the opening, the locking device being adjustable between a locking and an open position, the locking device having a locking head and a locking shaft connected to the locking head comprises, wherein the valve device has an overpressure control device and a thermostat device, wherein the thermostat device has a thermally reactive expansion element.

Valves of this type are used in certain situations to prevent, for example, fluid from passing from the input channel into the output channel or to prevent an impermissibly high pressure from building up in a fluid channel.

Basically, shut-off valves are differentiated from control valves, with manually operated, electric motor or magnetically operated or so-called medium-operated valves being used in both areas. The medium-operated valves are usually pneumatic or hydraulic valves, although a basic distinction must be made between self-medium-operated and external-medium-operated valves. While all indirectly controlled valves are valves operated by external medium, check valves, for example, are self-operated valves.

With a control valve, it is fundamentally possible to meter a volume flow, for example of a fluid, that is guided through the valve. For this purpose, a locking device already mentioned can typically be adjusted in numerous intermediate positions between a locking and an open position. In the case of a control valve actuated by its own medium, a parameter of the fluid to be dosed can be used to adjust the locking device, which can be, for example, the pressure of the fluid.

The object of the invention is to provide an improved way of adjusting a valve device.

DE 10 2006 003 271 A1 discloses a thermostatic valve, with an inlet and an outlet, and with a second inlet and a second outlet. The thermostat valve is connected to an oil circuit between a transmission and an oil cooler. The connection between the inlet channel and the outlet channel can be opened under thermal control alone via a valve slide element that is movable vertically relative to the inlet and outlet channel or to the inlet and outlet channel. For this purpose, a working piston arranged in a working housing is used, which can be moved via an expansion material and which is supported on a sealing plug. In the starting position shown, a bypass channel is open when the valve slide element is in the position closing the channel connection between the channels. The oil can flow from the inlet channel via the bypass into the outlet channel. As the temperature increases, the thermostatic working element increasingly opens the channel connection between the channels via the working piston, with the bypass described above being closed when a certain position is reached. In the working position, the oil can flow via the inlet to the outlet and backwards via the second inlet to the second outlet; both fluid connections are open. If there is excess pressure from the first inlet in this position, in which there is no bypass between the upper channel connection and the lower channel connection, this excess pressure can be used to press the valve slide element that is already in the open position a little further against the restoring force of a spring so that a two bypass is opened, through which the oil can flow from the first inlet past the valve slide element to the second outlet.

US 2015/0 277 453 A1 discloses a thermal valve for selectively opening and closing a first flow path, a second flow path and a third flow path within a valve housing by switching flow paths depending on a fluid temperature and a fluid pressure. It is used to control the flow and return of oil between a transmission and an oil cooler. The thermal valve has a valve chamber within a valve housing that is open to the first flow path via an opening. A thermocouple is provided which is arranged within the valve chamber so that the second flow path and the third flow path open into the valve chamber, the thermocouple being able to move back and forth within the valve chamber depending on the fluid temperature to the second Open and close the flow path and the third flow path.

US 5,738,276 A discloses a valve that can be operated by temperature and pressure. One design variant of the valve includes a valve seat that merges into a ring made of sheet metal and can be closed by a valve plate. The valve has an input side and an output side, with the input side located below the ring. On the output side above the ring, the valve plate is secured by a screw which is arranged between an arch attached to the ring and a formation of the valve plate, is pressed against the valve seat. If the overpressure of a fluid on the input side is greater than the preload force of the coil spring, the valve plate is moved towards the output side and the valve opens. On the input side below the ring, a thermostat is arranged in a housing on a second arch, through which a working piston can be moved to the output side or to the input side.

To solve this problem, in a valve device of the type mentioned at the outset, it is provided according to the invention that the input channel and the output channel are arranged axially to one another and the throttle axially follows the input channel, the locking device following the throttle axially and resting axially on the throttle in the blocking position can be moved both by the overpressure control device through a fluid pressure applied on the input channel side to the blocking device closing the throttle and by the thermostat device axially between the blocking and open positions, the thermally reactive expansion element being arranged in a cavity of the blocking shaft, on a position-fixed support device, which engages in the locking head and guides it, and is supported on an inside of the cavity of the locking shaft.

This means that, according to the invention, the locking device can be adjusted using two independent parameters of the fluid to be metered through the valve device. On the one hand, the overpressure control device can be set up in such a way that an opening of a fluid channel or a movement of the locking device from the locking to the open position takes place due to a pressure difference between the input and output channels. On the other hand, the thermostat device can be set up in such a way that an opening of the fluid channel or a movement of the locking device from the locking to the open position takes place due to the fluid temperature. Accordingly, it is possible according to the invention for the locking device to be moved from the locking position to an intermediate position by a specific fluid pressure and to be adjusted from the intermediate position to the open position when a specific fluid temperature is reached. On the other hand, it is also possible within the scope of the invention for the blocking device to be moved from the blocking position to an intermediate position when a certain fluid temperature is reached and to be adjusted from the intermediate position to the open position when a certain fluid pressure is reached. It is of course also within the scope of the invention that an opening of the fluid channel or a movement of the locking device from the locking to the open position takes place entirely through the overpressure control device or the thermostat device.

It is also within the scope of the invention that the overpressure control device has a restoring element and the thermostat device has a thermally reactive expansion element, the blocking device being movable from the blocking to the open position by a fluid pressure or by expansion of the thermally reactive expansion element against the restoring force of the restoring element. Accordingly, a valve device according to the invention can be set up in such a way that, regardless of whether the locking device is moved from the locking to an intermediate or the open position by the overpressure control device or the thermostat device, it is in any case moved out of the locking position of the valve device against a restoring force of a restoring element must become. As a result, the locking device of the valve device can be moved completely back from the open position or an intermediate position into the locking position by the restoring force of the restoring element, regardless of whether the locking device was moved from the locking to an intermediate or the open position by the overpressure control device or the thermostat device . Thus, in the event of an adjustment of the locking device from the locking to an intermediate or the open position by expanding the thermally reactive expansion element, it does not have to be ensured that the locking device is adjusted back from the open or an intermediate into the locking position by contracting the thermally reactive expansion element .

It can be provided that the restoring element is a spring element and/or the thermally reactive expansion element is a wax. The spring element can be, for example, a helical spring which is arranged on the locking device in such a way that the locking device can be adjusted from the closed to an intermediate or open position only against a restoring force of the helical spring. The spring element can, for example, be arranged on the locking device in such a way that the spring element must be adjusted against a restoring force by moving the locking device from the locking towards the open position. By using wax as a thermally reactive expansion element, the thermostat device can be set up in such a way that the wax expands when heated and contracts when it cools, so that the heating or the subsequent expansion of the wax causes the locking device to be moved by the thermostat device from the locking towards the open position is movable.

It is also within the scope of the invention that the locking device comprises a locking head and a locking shaft connected to the locking head. According to the invention, the locking head can be conical or at least partially spherical, so that it completely or almost completely closes the opening of the throttle in the locking position of the locking device. According to the invention, the locking shaft can be connected directly to the locking head and have a smaller cross-sectional area (transverse to the flow direction through the valve device) than the cross-sectional area of the locking head. The locking shaft can be either cylindrical or angular.

The blocking head can be linearly displaceable between the blocking and the open position in the flow direction along a longitudinal central axis of the valve device. This means that an end face of the locking head is exposed to the pressure of the fluid flow. Due to the linear displacement along the longitudinal central axis in the flow direction, the surface of the locking head exposed to the pressure of the fluid flow remains unchanged during the entire adjustment movement between the locking and open positions.

According to the invention, it can also be provided that the restoring element is arranged on the locking shaft between the locking head and a position-fixed guide of the locking shaft, the restoring element being supported on the position-fixed guide, so that the locking head moves against a restoring force of the restoring element from the locking to the open position and can be adjusted from the open to the locked position by the restoring force. If, as already mentioned, the restoring element is a spring element or a coil spring, it is within the scope of the invention that the restoring element surrounds the locking shaft. The restoring element can be arranged between the locking head and the position-fixed guide in such a way that it can be compressed by moving the locking head from the locking towards the open position of the locking device.

It is also within the scope of the invention that the thermally reactive expansion element is arranged in a cavity of the locking shaft and is supported on a position-fixed support device which engages in the locking head and guides it and on an inside of the cavity of the locking shaft, so that the locking head passes through Expansion of the thermally reactive expansion element against the restoring force of the restoring element from the locking to the open position and when contracting the thermally reactive expansion element by the restoring force of the restoring element from the open to the locking position is adjustable.

The cavity in which the thermally reactive expansion element is arranged can be formed by a recess on or in the locking shaft and/or locking head. The cavity preferably extends at least in sections along the locking shaft. The dimensions of the cavity exceed the dimensions of the contracted thermally reactive expansion element. This makes it possible for the expansion element to expand within the cavity.

If the expansion element expands, it is supported on the one hand by the support device, which engages in the locking head. On the other hand, the expansion element is arranged in the cavity in such a way that it is supported on the inside of the cavity, which is opposite the side on which the locking head is arranged on the locking shaft. The support device can engage so far into the locking head or into the cavity in which the thermally reactive expansion element is arranged, so that the support device lies flush against the expansion element, regardless of whether the expansion element is in a contracted or expanded state.

The support device can be a web or a web-like component. The locking head can be provided with an opening which can be adapted to the dimensions of the support device to the extent that its diameter and shape are chosen such that the support device corresponds to the opening in such a way that it is completely or almost completely sealed by the engaging support device is. This can prevent the expanding expansion element from emerging from the cavity of the locking device. The thermally reactive expansion element arranged in the cavity can have a larger cross-sectional area than that of the part of the support device engaging in the locking head. A further component can be arranged between the part of the support device engaging in the locking head and the expansion element. This further component can consist of a non-elastic material and have a cross-sectional area that corresponds to the cross-sectional area of the expansion element. This can prevent the larger cross-sectional area of the expansion element compared to the support device from having the effect that the expansion element expands laterally along the support device during expansion and thus a supporting lifting movement of the thermally reactive expansion element would not occur.

It is also within the scope of the invention that the valve device has a leakage groove, with a pilot current of. independent of a position of the locking device through the leakage groove the input channel can be generated in the output channel. The leakage groove can be created by the blocking device not completely closing the opening of the throttle of the valve device even in the blocking position of the blocking device. As a result, in the blocking position of the blocking device, there can be a relatively narrow gap between the blocking device or the blocking head and the throttle, through which a certain part of a fluid flowing into the input channel can flow into the output channel, whereby the pilot current can be generated. However, it is also within the scope of the invention that the leakage groove is designed as a second opening in the throttle of the valve device, which also establishes a connection between the input channel and the output channel but cannot be closed by the locking device.

According to the invention, it can be provided that the pilot flow can be guided along the blocking device, so that the temperature of the fluid of the pilot flow can be transferred to the thermally reactive expansion element of the thermostat device. Accordingly, regardless of whether the locking device is in the locking or open position, a pilot current can be guided in such a way that it flows past the locking device and the temperature of the fluid flowing past is thus permanently adjusted to that arranged in the locking shaft, regardless of the position of the locking device thermally reactive expansion element of the thermostat device can be transferred. This leads to reliable control or regulation of the thermostat device, since temperature transfer between the fluid and the thermally reactive expansion element is possible in any operating state of the valve device. Within the scope of the invention, however, it may be preferred that even a small amount of fluid in the pilot flow, which has not yet reached a certain temperature, does not reach the outlet channel of the valve device. Consequently, it is also within the scope of the invention that the pilot current can be guided in such a way that it flows past the locking device, so that a temperature transfer to the thermally reactive expansion element arranged in the locking shaft is made possible, but this before it enters the output channel of the Valve device can enter the input channel of the valve device or can be (returned) to another channel.

In addition, the invention relates to a motor vehicle with at least one valve device according to the invention. All statements regarding the valve devices continue to apply analogously to the motor vehicle.

• 1 eine erfindungsgemäße Ventilvorrichtung in einer seitlichen Ansicht; und
• 2 eine weitere seitliche Ansicht der in 1 gezeigten Ventilvorrichtung.

Further advantages and details of the invention are explained below using an exemplary embodiment with reference to the drawings. The drawings are schematic representations and show:

• 1 a valve device according to the invention in a side view; and
• 2 another side view of the in 1 valve device shown.

1 shows a valve device 1 through which a connection between an input channel 2 and an output channel 3 can be established. The valve device 1 is arranged between two pipes 15, 16 in such a way that the valve device 1 can establish a connection between the two pipes 15, 16 when the locking device 4 is adjusted from the locking to an intermediate position or the open position. For this purpose, there is a locking device 4 within the valve device 1, which includes both a locking head 5 and a locking shaft 6. The locking head 5 is firmly connected to the locking shaft 6, the locking shaft 6 in the side view having a rounded contour on one side and having a larger cross-sectional area in comparison to the locking shaft 6. Due to the larger cross-sectional area of the locking head 5, a protruding edge of the locking head 5 relative to the locking shaft 6 is created at the connection to the locking shaft 6, resulting from the difference in the cross-sectional areas.

A restoring element 7 is arranged on the locking device 4 or on the locking shaft 6 in such a way that the restoring element 7 is supported on the previously described protruding edge between the locking head 5 and the locking shaft 6. The restoring element 7 is a spring element such as a coil spring. A thermally reactive expansion element 8 in the form of a wax is arranged within the locking shaft 6. The expansion element 8 is arranged in a cavity 9 provided for this purpose. The cavity 9 is formed by a recess in the locking shaft 6 and extends along the locking shaft 6. The locking shaft 6 and the expansion element 8 made of wax essentially form a wax cartridge. The dimensions of the cavity 9 exceed the dimensions of the expansion element 8 in the cold, unstretched state such that the expansion element 8 is sufficiently expandable to move the locking device 4 from the locking to the open position. In addition, a throttle 10 with an opening 11 is arranged between the input channel 2 and the output channel 3, which is almost closed by the locking head 5 of the locking device 4. Between the locking head 5 and the opening 11 and the throttle 10 remains itself In the locked state of the locking device 4, a leakage groove 12 in the form of a narrow gap between an edge of the throttle 10 in the area of the opening 11 and the locking head 5. Thus, even in the locked state of the locking device 4, a small part of a fluid flow flowing into the inlet channel 2 can flow from the inlet channel 2 reach the output channel 3. The small portion of the fluid flow passing through the leakage groove 12 flows in the form of a pilot flow directly along the locking head 5 and the locking shaft 6, so that the temperature of the pilot flow is independent of a position of the locking device 4 on the thermally reactive expansion element 8 arranged in the locking shaft 6 is transferable.

Thus, the locking device 4 is within the scope of in 1 shown valve device 1 both by a pressure of a fluid flow acting on the locking head 5 and by the temperature of a pilot flow passing through the leakage groove 12, which can be transferred to the thermally reactive expansion element 8 arranged in the locking shaft 6, from a locking to an open position movable. Both in the pressure-controlled and in the temperature-controlled movement of the locking device 4 from the locking to the open position, the movement of the locking device takes place against a restoring force of the restoring element 7. A position-fixed support device 13 and a position-fixed guide 14 always ensure that the locking device 4 is guided accordingly. The support device 13 and the guide 14 are fastened in a suitable manner in the housing of the valve device so that fluid can flow past it. As in 2 clearly shown, the position-fixed guide 14 is arranged in the valve device 1 in such a way that the locking shaft 6 can slide at least partially along the position-fixed guide 14 and is guided accordingly. The restoring element 7 is arranged on the locking shaft 6 in such a way that, as previously mentioned, it is supported on the one hand on the edge between the locking head 5 and the locking shaft 6 and on the other hand on the position-fixed guide 14, which is designed to guide the locking shaft 6. In addition to the pressure-controlled movement of the locking device 4, a temperature of a fluid flowing along the locking shaft 6 through the pilot flow is permanently transferred to the thermally reactive expansion element 8 arranged in the locking shaft 6, so that the expansion element 8 expands through the temperature transfer or reaches a certain temperature and On the one hand, it is supported on the support device 13, which engages in the locking head 5 and is also fixed in position, and on the other hand, it acts against one side within the locking shaft 6, so that the locking device 4 is moved from its locking position into an intermediate position or its open position.

In 2 is another side view of the in 1 shown valve device 1, wherein the thermally reactive expansion element 8, which is arranged in the locking shaft 6 of the locking device 4, expanded in such a way that the locking device 4 was moved from its locking position to its open position. It is clearly shown that the cavity 9, which is part of the illustration 1 can still be clearly seen, within the locking shaft 6 is completely filled by the expanded thermally reactive expansion element 8, whereby the locking device 4 was moved from the locking position into the open position against the restoring force of the restoring element 7.

Claims (8)

Valve device (1) with an inlet channel (2), an outlet channel (3), a throttle (10) with an opening and a locking device (4) for closing the opening, the locking device being adjustable between a locking and an open position, wherein the locking device (4) comprises a locking head (5) and a locking shaft (6) connected to the locking head (5), the valve device (1) having an overpressure control device and a thermostat device, the thermostat device having a thermally reactive expansion element (8), characterized in that the input channel (2) and the output channel (3) are arranged axially to one another and the throttle (10) axially follows the input channel (2), the axially following the throttle (10) and in the blocking position axially on the throttle (10) applied locking device (4) can be moved axially between the locking and open positions both by the overpressure control device through a fluid pressure applied on the input channel side to the locking device (4) closing the throttle (10) and by the thermostat device, the thermally reactive expansion element (8) is arranged in a cavity of the locking shaft (6), is supported on a position-fixed support device (13), which engages in the locking head (5) and guides it, and on an inside of the cavity of the locking shaft (6). Valve device (1). Claim 1 , characterized in that the overpressure control device has a restoring element (7), the locking device (4) being movable from the blocking to the open position by a fluid pressure or by expansion of the thermally reactive expansion element (8) against the restoring force of the restoring element (7). . Valve device (1). Claim 2 , characterized in that the restoring element (7) is a spring element and/or the thermal reactive expansion element (8) is a wax or a wax cartridge. Valve device (1) according to one of the preceding claims, characterized in that the blocking head (5) is linearly displaceable between the blocking and open positions in the flow direction along a longitudinal central axis of the valve device (1). Valve device (1). Claim 2 or 3 , characterized in that the restoring element (7) is arranged on the locking shaft (6) between the locking head (5) and a fixed-position guide (14) of the locking shaft (6), the restoring element (7) being located on the fixed-position guide (14). supported, so that the locking head (5) can be adjusted from the locking to the open position against a restoring force of the restoring element (7) and from the open to the locking position by the restoring force. Valve device (1) according to one of the preceding claims, characterized in that it has a leakage groove (12), a pilot flow from the inlet channel (2) into the outlet channel (12) through the leakage groove (12), regardless of a position of the locking device (4). 3) can be generated. Valve device (1). Claim 6 , characterized in that the pilot flow can be guided along the blocking device (4), so that the temperature of the fluid of the pilot flow can be transferred to the thermally reactive expansion element (8) of the thermostat device. Motor vehicle with at least one valve device (1) according to one of the preceding claims.

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