DE102021134013A1 - Vehicle Seating System - Google Patents

Abstract

A vehicle seating system includes a vehicle seat and a pneumatic system. The pneumatic system has the following components: at least one fluid actuator, preferably housed in the vehicle seat, a plurality of piezoelectrically operated pumps, a common line system. The piezoelectric pumps are in fluid communication with one another and with the at least one fluid actuator via the line system. The pumps can be controlled in such a way that they influence the fluid pressure and/or the fluid flow in the line system and thus the fluid pressure in the at least one fluid actuator and/or the fluid flow into or out of the at least one fluid actuator.

Description

The invention relates to a vehicle seat system, which includes a vehicle seat and a pneumatic system with which seat functions can be controlled and executed.

Such pneumatic systems usually have fluid actuators that are supplied with fluid, which can be air, for example, via a pump. By selectively controlling the fluid actuators, which are preferably fluid-fillable bladders, they can be used in a vehicle seat, for example, to adjust the seat or to implement a massage function.

According to the prior art, the actuation takes place via a system of lines, valves and a pump, which supplies the line system and thus the valves and ultimately also the fluid actuators with fluid, or draws fluid from the fluid actuators. This places high demands on the selection of the components used and the performance of the pump used, since rapid filling and emptying ensure the high dynamics of a fluid actuator.

On the other hand, the corresponding control units to which the fluid actuators are connected are often integrated into vehicle seats. In general, with increasing mechanization in the field of vehicle seats, space for accommodating components is scarce on the one hand, and on the other hand such systems must be economical to produce in view of the manufacturing costs.

The object of the present invention is to specify a vehicle seat system that meets the criteria mentioned without having to accept corresponding losses in terms of functionality.

This problem is solved by a vehicle seat system with the features of claim 1. Advantageous embodiments can be found in the dependent claims.

According to the invention, the vehicle seat system includes a vehicle seat and a pneumatic system. The latter has as components at least one fluid actuator, preferably housed in the vehicle seat, a plurality of piezoelectrically operated pumps and a common line system. The piezoelectric pumps are in fluid connection with one another and with the at least one fluid actuator via this common line system. In this case, fluid connection means that a fluid flow can occur between two components connected to one another via the fluid connection. Of course, such components can also be barriers or valves that at least temporarily prevent fluid flow. According to the invention, the pumps can be controlled in such a way that they influence the fluid pressure and/or the fluid flow in the line system and thus the fluid pressure in the at least one fluid actuator and/or the fluid flow into or out of the at least one fluid actuator.

Piezoelectric pumps have a relatively small installation space, but bring with them a sufficient delivery rate, so that they are suitable for the present application. Also, due to the small installation space and the relatively low costs of such a piezoelectric pump, a plurality of piezoelectric pumps can be accommodated in a relatively small space. The piezoelectric pump(s) can be a disk pump, a membrane pump or an ultrasonic pump, for example. While there are a number of different fluid actuators, it is preferred that at least one fluid actuator comprises a pneumatic bladder.

The inventive combination of a plurality of piezoelectric pumps via a line system results in a whole series of advantages. A major advantage is that the pumps can either be used to support each other, i.e. to increase the delivery rate, i.e. ultimately the fluid flow in the pipe system, and to be able to fill a certain volume more quickly. On the other hand, it is possible to implement filling processes by controlling a first piezoelectric pump and emptying processes by controlling a second piezoelectric pump. In this way, different scenarios can be mapped and, with a corresponding number of piezoelectric pumps, may make the use of additional valves, i.e. additional expensive components, unnecessary.

According to a preferred embodiment of the present invention, the pumps can be controlled, for example, in such a way that they can convey fluid monodirectionally and/or bidirectionally. Corresponding actuation is performed by a control device which, like the piezoelectric pumps, can be electrically contacted on a printed circuit board, for example, so that the piezoelectric pumps can be actuated via the conductor tracks of the printed circuit board.

In addition to the targeted control of the pumps, their arrangement or fluidic connection also plays a role in the question of how different systems of fluid actuators can be operated. In general, there is the possibility to connect two or more than two piezoelectric pumps in series or to connect them in parallel to fill or empty a fluid actuator. According to the invention, provision can therefore be made for the or some of the pumps to be in fluid communication with one another in series and/or in parallel via the line system. If two or more piezoelectric pumps are connected in series with the same delivery direction, i.e. one pump uses the fluid on the suction side, which is delivered on the pressure side of another pump, the delivery rate remains constant but the pressure in the pipe system increases. If, on the other hand, two or more pumps are connected in parallel, the pressure in the line system remains constant and the pumping capacity increases in accordance with the number of pumps connected in parallel.

The latter can be realized, for example, in that the line system comprises at least one common rail, which is in fluid connection with at least one fluid actuator via at least one actuator line and via which at least two of the pumps are in fluid connection parallel to one another. Of course, in this embodiment, both pumps can be operated with the same delivery direction and/or the control device can be operated in such a way that the two pumps have a different delivery direction. In this case, for example, the filling process of the fluid actuator can be regulated by one pump, while the evacuation process of the fluid actuator is taken over by the other pump.

Alternatively or additionally, it can be provided that at least two pumps are connected to one another in series and are in fluid communication with at least one fluid actuator via an actuator line. In this embodiment, the pressure that can be achieved in the line system and thus also in the fluid actuator is increased in comparison with the use of a single piezoelectric pump in accordance with the number of pumps connected in series.

• 1 - zeigt schematisch einen Teil eines erfindungsgemäßen Fahrzeugsitzsystems in einer ersten Ausführungsform,
• 2 - zeigt schematisch einen Teil eines erfindungsgemäßen Fahrzeugsitzsystems in einer zweiten Ausführungsform,
• 3 - zeigt schematisch einen Teil eines erfindungsgemäßen Fahrzeugsitzsystems in einer dritten Ausführungsform,
• 4 - zeigt schematisch einen Teil eines erfindungsgemäßen Fahrzeugsitzsystems in einer vierten Ausführungsform.

The invention is based on the 1 - 4 explained in more detail. Basically, whenever pumps are mentioned, piezoelectric pumps are meant. Whenever the word fluid is used, it can be any flowable medium, but air is preferred. Fluid actuators can be any actuators influenced by the fluid, but bladders that can be filled with fluid and have a flexible outer shell that is impermeable to the fluid are preferred.

• 1 - shows schematically a part of a vehicle seat system according to the invention in a first embodiment,
• 2 - shows schematically a part of a vehicle seat system according to the invention in a second embodiment,
• 3 - shows schematically a part of a vehicle seat system according to the invention in a third embodiment,
• 4 - shows schematically a part of a vehicle seat system according to the invention in a fourth embodiment.

At the in 1 In the first embodiment shown, a plurality of piezoelectric pumps 11, 21, 31, 41 are fluidically connected via corresponding lines 211, 221, 231, 241 to a common line 2, for example a common rail. The dashed lines indicate that at least two piezoelectric pumps, but also more than two such pumps, can be used to achieve the object according to the invention. All of the lines 2, 211, 221, 231, 241 and the actuator line 3 leading from the line 2 to the fluid actuator 4 form the common line system L, via which the pumps 11-41 are connected to at least one fluid actuator 4. In the illustrated exemplary embodiment of the pneumatic system 1, the line system L is designed in such a way that the pumps 11-41 are connected in parallel to one another. This causes the delivery rates of the pumps 11 - 41 to add up with the same pumping direction. It is of course possible to use individual pumps 11 - 41 to pump fluid, preferably air, out of line 2 and thus out of fluid actuator 4 as well. Depending on the control, the fluid actuator can be filled or emptied. The controller can also provide for one or a plurality of pumps 11-41 to work bidirectionally, for example when the fluid actuator 4 has to be periodically filled or emptied to implement a massage function, for example.

At the in 2 In the pneumatic system 1 shown, the pumps 11, 12 and 13 (the latter in turn are optional and are therefore indicated by dashed lines) are connected in series. The pump 13 is connected to the pump 12 via a line 311 , which in turn is connected to the pump 11 via a line 211 . The latter is connected to the fluid actuator 4 for control purposes via an actuator line 34 . The series connection of the pumps 11 - 13 does not change the delivery rate, but the fluid pressure with which the fluid is pumped into the fluid actuator 4 increases according to the number of pumps. This means that in the fluid actuator 4, depending on the number of pumps used, 11 - 13 higher pressures are generated. Here, too, the total number of lines used forms the line system L.

The in the 1 and 2 The pneumatic systems 1 shown have pumps 11-41 connected purely in parallel or pumps 11-13 connected purely in series. Of course, these circuit forms of the pumps can also be combined.

Another embodiment is in 3 shown. Here there are series circuits of two pumps 11, 12 (connected via line 211) or 21, 22 (connected via line 221) or further optional pump series 31, 32 (connected via line 231) or 41, 42 (connected via line 241). Each of these rows of pumps is connected to the common line 2 via a corresponding line 111 or 121 or 131 or 141. In this way, in contrast to the embodiment in FIG 1 not only multiplies the flow rate according to the number of pump rows, but also increases the achievable pressure.

In the embodiment according to 4 the pneumatic system differs from the embodiment in 3 in that an additional common line 5 or common rail is used, which is fluidically connected to the lines 211, 221, 231, 241. In this way, it is possible to selectively address individual pumps in order to achieve a desired flow profile and, if necessary, also to have them work simultaneously with different flow directions. For example, individual pumps (for example pumps 22 and 11) with different delivery rates could also be combined with one another, depending on which function the fluid actuator 4 is intended to perform. By integrating a second common line 5, possibly at least one further common line, a kind of pump matrix is created, which is controlled via the control of the pneumatic system 1, which is not shown here.

In all of the embodiments, only a single fluid actuator 4 is shown as an example. However, it goes without saying that a plurality of fluid actuators 4 can also be connected to the line system L according to the invention, which can then be filled or emptied by one or a plurality of the pumps used.

Claims (7)

Vehicle seat system, comprising a vehicle seat and a pneumatic system (1), which has the following components: at least one fluid actuator (4), preferably housed in the vehicle seat, a plurality of piezoelectrically operated pumps (11 - 41, 12 - 42), a common line system (L) via which the piezoelectric pumps (11 - 41, 12 - 42) are in fluid connection with each other and with the at least one fluid actuator (4), so that the pumps (11 - 41, 12 - 42) can be controlled in this way are that they affect the fluid pressure and/or the fluid flow in the line system (L) and thus the fluid pressure in the at least one fluid actuator (4) and/or the fluid flow into or out of the at least one fluid actuator (4). vehicle seating system claim 1 , characterized in that the pumps (11 - 41, 12 - 42) can be controlled in such a way that they can pump fluid monodirectionally and/or bidirectionally. Vehicle seat system according to one of the preceding claims, characterized in that the or some of the pumps (11-41, 12-42) are in fluid communication with one another in series and/or in parallel via the line system (L). Vehicle seat system according to one of the preceding claims, characterized in that the line system (L) comprises at least one common rail (2, 5) which is in fluid communication with the at least one fluid actuator (4) via at least one actuator line (3) and via which at least two of the pumps (11-41; 12-42) are in fluid communication with each other in parallel. Vehicle seat system according to one of the preceding claims, characterized in that at least two pumps (11 - 13) are connected to one another in series and are in fluid communication with at least one fluid actuator (4) via an actuator line (34). Vehicle seat system according to one of the preceding claims, characterized in that the piezoelectric pump(s) (11-41, 12-42) is a disk pump, a membrane pump or an ultrasonic pump. Vehicle seating system according to one of the preceding claims, characterized in that at least one fluid actuator (4) comprises a pneumatic bladder.

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