EP1658195A1

EP1658195A1 - Motor vehicle seat ventilation module

Info

Publication number: EP1658195A1
Application number: EP04769144A
Authority: EP
Inventors: Didier Loup; Vincent Feuillard; Frédéric Giraud
Original assignee: Valeo Systemes Thermiques SAS
Current assignee: Valeo Systemes Thermiques SAS
Priority date: 2003-08-29
Filing date: 2004-08-19
Publication date: 2006-05-24
Also published as: FR2859146A1; JP2007504035A; CN1839060A; FR2859146B1; WO2005021320A1; CN100475604C

Abstract

A module including a housing (4) and an air flow channel (6) provided in the housing (4) for generating an air flow therethrough. A seat air duct enables air to flow through at least one seat (12). A heating resistor (28) is provided in the air flow channel. An air blower (14) generates an air flow between the seat air duct (8) and the air flow channel (6). A second air flow channel (46) may be provided for generating a second air flow through the housing (4). An air flap (48) enables the first and second air flows to be mixed with a variable mixture ratio.

Description

Motor vehicle seat ventilation module.

The invention relates to air conditioning of the passenger compartment of a motor vehicle, to its heating and to its ventilation, particularly of the seats of this vehicle.

Current motor vehicles are equipped with a heating and ventilation device which blows hot air into the passenger compartment of the vehicle in the event of low outside temperature or, on the contrary, ventilate fresh air to cool it. Many of these devices are also equipped with an air conditioning circuit which effectively lowers the temperature inside the vehicle, especially in summer.

In order to always provide more comfort to the driver and passengers, it has appeared desirable to heat or ventilate the seats of the vehicle more particularly. We already know (US 6,478,369; US 5,921,100; US 6,059,018) a certain number of devices intended for this application. One of these documents describes a seat ventilation device which blows air through a porous lining. The air flow is not reversible and comfort is not significantly improved. A second document describes a device for ventilating a seat by sucking air through a porous lining of the seat. This device is only effective in summer. In addition, the air flow is not reversible. A third document describes a seat ventilated by air circulation inside the seat, without orifices allowing the air to exit. This device is not very effective and the feeling of hot or cold does not manifest itself until after a long period of time.

Yet another document describes seat heating by means of heating layers. This device is only effective than in winter. In addition, the sensations it produces are not pleasant.

The need therefore arises for a heating, ventilation and / or air conditioning device having more extensive functionalities and which allows, in particular, a reversal of the air flow, which is adjustable independently of the temperature of the appliance. main air conditioning and ventilation of the passenger compartment. This device should be inexpensive and modular so that it can be an option for each seat.

To this end, the invention provides a seat ventilation module, in particular for a motor vehicle, characterized in that it comprises a housing, at least one air passage arranged in the housing to circulate an air flow in the housing, a seat air passage for circulating air through at least one seat, heating means in the air passage, an air blower for circulating an air flow between the passage seat air and air passage.

Advantageously, the module comprises at least a second air passage for circulating a second air flow in the housing, a mixing flap capable of moving between a first position in which it closes the first air passage and a second position in which it closes the second air passage to mix the first and second air flows in variable proportion.

Thus, the temperature of the air flow passing through the seat can be adjusted independently of that of the main heating and ventilation device of the passenger compartment. This air flow can in particular be heated by virtue of the presence of the heating means, for example an electrical resistance with a positive temperature coefficient. In a preferred embodiment, the blower is capable of blowing or aspirating a flow of air through the seat. This result can be obtained, for example, by reversing the direction of rotation of the blower.

In another embodiment, the blower is disposed in a duct having first and second ends, a first flap being disposed at the first end of the duct and a second flap being disposed at its second end, the first and second flaps being designed so as to put the first and second ends of the duct in communication either with the seat air passage or with the air passage.

Thanks to these characteristics, it is possible to blow an air flow in the seat through a porous lining. Or, conversely, it is possible to draw air through the seat, depending on the most effective method.

In a particular embodiment, the second air passage is connected by an air intake pipe to the ventilation, heating and / or air conditioning device of the vehicle.

In particular, this air intake pipe can be connected to the ventilation, heating and / or air conditioning device of the vehicle at the outlet of an evaporator housed in this device. Cold air is thus taken which effectively cools the seats in the event of a high outside temperature.

In an alternative embodiment, the air intake pipe is connected to a mixing chamber of the ventilation, heating and / or air conditioning device of the vehicle. It is thus possible to take air at a regulated temperature.

One can also provide in the seat an evacuation passage allowing the outlet of the blown air through the seat. According to another embodiment, a shutter inlet and / or an evacuation flap are provided to close an inlet passage and / or the evacuation passage during normal operation of the module.

When the vehicle is stationary, no means are provided for cooling the air in the passenger compartment. Therefore, the vehicle in the sun sees the temperature of its passenger compartment increase, and there occurs on the air of this passenger compartment an operation of "chambering", that is to say that this air sees its temperature increase with the passenger compartment . A module of the type described above makes it possible to evacuate this air from the seats of the vehicle, and therefore to "dechamber" the seats in a phase of putting the module into operation, which makes it possible to cool them.

The module can be mounted on the vehicle floor, a deformable duct connecting the seat air passage to at least one seat.

Alternatively, the module can be mounted directly under the seat of a vehicle seat. Finally, the module can be placed in the center console of the vehicle and connected by a left seat duct to the left seat and by a right seat duct to the right seat of the vehicle.

In a variant of the invention, the module includes an electronic card to control it, located in the passage or the second air passage. In another variant, it includes an electronic card to control the module, located in the air intake pipe. Advantageously, the electronic card includes means for calculating leak detection.

The module can also be associated with a group of seats, for example the front seats.

To allow the passage of air, where micro perforations are made in the seat upholstery, in a known manner, both in the seat and in the seat back. Other characteristics and advantages of the invention will become apparent on reading the following description of embodiments given by way of illustration with reference to the appended figures. In these figures:

- Figure 1 is a schematic sectional view of a ventilation module according to the invention comprising a single air duct;

- Figure 2 is a schematic sectional view of a ventilation module comprising two air ducts;

- Figure 3 is a sectional view along line III-III of the ventilation module of Figure 2;

- Figures 4 and 5 schematically show a ventilation module for reversing the air flow;

- Figures 6 and 7 are side and front views of a vehicle seat having air diffusion pockets;

- Figures 8 and 9 are schematic views of a ventilation module connected to the ventilation, heating and / or air conditioning of the vehicle;

- Figure 10 is a schematic sectional view of a variant of the module of Figure 1;

- Figure 11 is a schematic sectional view of a variant of the module of Figure 5;

- Figure 12 is a schematic sectional view of a variant of the module of Figure 1; Figure 13 is a schematic sectional view of a variant of the module of Figure 4; and FIG. 14 is a schematic sectional view of part of a variant of the module of FIG. 9.

There is shown in Figure 1 a schematic perspective view of a first embodiment of a motor vehicle seat ventilation module 2 according to the present invention.

It comprises a housing 4 in which is arranged an air passage 6 and a seat passage 8. The seat air passage 8 is connected by a seat air duct 10 to a seat 12. The duct 10 can be deformable, for example telescopic or flexible in order to allow a variation of the position of the seat 12 relative to the ventilation module 2, in particular when it is desired to adjust the height of the seat. A blower 14 is arranged inside the housing 4. This blower allows air to be drawn in through the air passage 6, as shown diagrammatically by the arrow 16 when the blower 14 rotates in the direction of rotation shown by the arrow 18. The air is blown through the seat air passage 8 as shown schematically by arrow 20 to a pocket 22 formed in the seat. The seat upholstery is porous or micro-porous so as to allow air to pass through it as shown schematically by the arrows 23.

The seat 12 can also include a pocket 24 provided in the seat back and connected to the pocket 22 by conduits which allow the passage of air (not shown). The back upholstery is also porous or micro-porous so as to allow air to pass through it.

Advantageously, a dust filter 26 is placed at the inlet of the seat air passage 6 so as to retain the dust present in suspension in the aspirated air. Heating means, for example electrical resistors, in particular resistors with a positive temperature coefficient (PTC) are placed after the air filter. The electric heaters heat the air sent to the pockets 22 and 24.

The direction of rotation of the blower 14 can be reversed so that it rotates in the direction shown by the arrow 30. In this case, instead of sucking the air through the air passage 6, the air is sucked through the linings of the seat and the seat back 12 as shown schematically by the arrows 32 shown in dotted lines. The air inspired through the seat linings passes into the housing through the seat air duct 10, as shown in the arrow 34, then is discharged outside the housing, as shown by the arrow 36. The seat ventilation module 2 in FIG. 1 can operate in different modes. In summer, air can be drawn through the seat upholstery to cool it down. Conversely, it is possible to draw air into the passenger compartment of the vehicle and to blow it through the linings. On the contrary, when it is desired to warm the seat, for example in winter, the module can operate only in blowing mode. The air is sucked in, as shown by arrow 1, then heated by passing over the electrical resistors 28 before being sent into the seat and the seat back 12.

The electrical resistances CTP 28 can operate in all or nothing, or else, in a more elaborate embodiment, they can be stepped so as to adjust their power at different levels as a function of the desired temperature. It will further be observed that this module operates completely independently of the main vehicle's ventilation, heating and / or air conditioning apparatus. In addition, it can operate even if the vehicle is not equipped with an air conditioning system.

As a variant, this module can be completed to present a start-up phase called "dechambrage". Dehulling is useful for evacuating the heated air accumulated in seat 12. For this purpose, as can be seen in FIG. 10, the seat 12 is provided with an evacuation passage 200 opening into the pocket 22 on the one hand and outside the seat 12 on the other hand, The placing the pocket 22 in communication with the outside of the seat 12 is controlled by the evacuation flap 202 which opens or closes the evacuation passage 200. According to the embodiment, to supply the air necessary for dechambrage at blower 14, the housing 4 is also provided with an inlet passage 204 and an inlet flap 206.

The dechambering is carried out by opening the inlet flap 206 and the discharge flap 202. The blower 14 then circulates air 208. The air 208 enters the pocket 22 thus creating a circulation allowing evacuation 210 heated air initially accumulated in the pocket 22 of the seat 12, through the evacuation passage 200. Thus, it is possible to evacuate a certain amount of heat accumulated in the seat 12 before operating the module as described more high. The air 208 can be air taken downstream of the heating means 28 or recycled air taken under the seat or air taken upstream of the heating means 28.

During normal operation of the module, the discharge flap 202 and the entry flap 206 are both closed. Such a module therefore makes it possible to avoid, at startup, ventilating the passenger with air whose temperature is considerably elevated by the heat retained by the seat.

As a variant, only the discharge passage 200 is used, and the inlet passage 204 is constituted by the air passage 6, the dechambrage being carried out before the use of the heating means 28.

In the example described here, the déchambrage is carried out on the pocket 22, but it can also be carried out on the pocket 24 or both as required. FIGS. 2 and 3 show respectively a vertical section view and a horizontal section view of a second embodiment of a seat ventilation module according to the invention. It differs from the previous embodiment shown in Figure 1 by the fact that it has a second air passage 46 parallel to the first air passage 6. Unlike passage 6, passage 46 does not have an electric heating resistance . However, it can optionally be fitted with a dust filter. A mixing flap 48 articulated around an axis 50 makes it possible to completely block the first air passage 6 or the second air passage 46 as shown in FIG. 2. When the second passage is completely closed, the air flows entirely through the first pass and vice versa. The mixing flap 48 can also occupy all the intermediate positions between the extreme positions described above so as to mix in variable proportion the air flows which circulate through the first and the second passages. It is thus possible to adjust the temperature of the air blown into the seats by mixing in the desired proportion the hot air heated by the electric resistors 28 (passage 6) and the air at ambient temperature inspired in the passenger compartment of the motor vehicle originating of the second passage 46. The ventilation module is equipped with an electric motor 50 whose axis is arranged vertically. This motor drives a paddle wheel 52 arranged in a volute 54 which makes it possible to blow air through the seat passage 8 connected to one or more seats 12 of the vehicle by a seat duct not shown. In this embodiment, unlike the previous one, the direction of rotation of the blower 52 cannot be reversed. This module can therefore operate in the ventilation mode of the seat by blowing fresh air through their lining, the electrical resistances 28 then being cut off, or else it can operate in heating mode, the hot air produced by the electrical resistances 28 being able to to be mixed in variable proportion to lower temperature air admitted by the second air intake passage 46.

There is shown in Figures 4 and 5 a third embodiment of a seat ventilation module according to the invention. Like the embodiment of FIGS. 2 and 3, it comprises a first air passage 6 in which are fitted a dust filter 26 and electrical resistances with a positive temperature coefficient 28 and a second air passage 46, a shutter mixing 48 articulated around its axis 50 allows, as described above, to mix in variable proportion the air flows from the first and second air passages.

In this embodiment, the blower 14 is disposed in a duct having a first open end 60 and a second open end 62. A first flap 64 articulated around an axis of rotation 66 is disposed opposite the first open end 60, while qu 'a second flap 68 articulated around an axis of rotation 70 is disposed opposite the second open end 62 of the conduit 58. The flap 64 can occupy a first position shown in solid lines in Figure 4 in which it puts in communication the open end 60 of the conduit 58 with the exterior of the housing 4, in particular by means of the second air passage 46 left open by the mixing flap 48. The flap 64 can also occupy a second position shown in dotted lines in FIG. 4 in which the first open end of the duct 58 is in communication with the seat air passage 8 and therefore, via the seat air duct e 10 with the pockets 22 and 24 disposed respectively in the seat and in the back of one or more seats 12. In the same way, the second flap 68 is movable between a position shown in solid lines in FIG. 4 in which the second open end 62 of the conduit 58 is in communication with the passage 8 for seat air, as shown diagrammatically by the arrows 74 and 76 and a second position shown in dotted lines on the Figure 4 in which the second open end 62 of the conduit 58 is in communication with the outside of the housing, in particular by means of the second air passage 46. It will be noted that the flaps 54 and 58 do not occupy a position intermediate between the two positions described above.

In the position shown in Figure 4, air is inspired through the seat linings by the blower 14, as shown in the arrows 74 and 76 and released to the outside of the ventilation module, as shown in the arrow 72 through the passage 46. On the contrary, in the position shown in FIG. 5, the air is inspired into the passenger compartment of the motor vehicle by the air passage 46, as shown diagrammatically by the arrows 78 and blown into the linings of the seat 12 as shown schematically by the arrow 80. Thus, thanks to the play of the first and second flaps 64, 68, it is possible to reverse the direction of the air flow while maintaining the same direction of rotation of the blower 14. From in this way, the ventilation module can operate either in inspiration mode or in blowing mode. When operating in inspiration mode, there is obviously no need to heat the air discharged into the passenger compartment. This is the reason why the first air passage 6 is in the closed position. The CTP 28 electric resistors are stopped. On the contrary, in the blowing position, the ventilation module can operate in two different ways. The mixing flap 48 can be in the closed position, shown in solid lines in FIG. 5, so as to blow air as fresh as possible in the seats of the vehicle. It is this operating mode that will be used in summer.

As a variant, as illustrated in FIG. 11, this module can be provided with a clearance function with the discharge passage 200, the clearance passage 204, the discharge flap 202, and the deflashing flap 206 which operate. like those of FIG. 10. In another variant, only the discharge passage 200 is used, and the inlet passage 204 is constituted by the air passage 6 or the second air passage 46, the dechambrage being carried out before the use of the heating means 28.

FIG. 6 shows a side view and in FIG. 7 a front view of a seat 12 ventilated using the ventilation module of the invention. Figures 6 and 7 allow to assess the shape and arrangement of the seat pocket 22 and the diffusion pocket 24 housed in the seat back. The pockets 22 and 24 are connected to the seat ventilation module 2 disposed directly on the floor 80 of the vehicle by two flexible conduits 10 which allow the seat to move up and down so as to adapt its position to the size of the driver or 'a passenger.

FIG. 8 shows a schematic view which illustrates an alternative embodiment of the ventilation module of the invention. In this variant, the external passage 46 is connected by an air intake pipe 82 to the vehicle ventilation, heating and / or air conditioning device 84. This device, shown schematically in FIG. 8, includes a blower 86 which circulates an air flow through the device. This air flow passes through an evaporator 90. A heating radiator 92 is arranged downstream of the evaporator 90. A mixing flap 94 makes it possible to mix in variable proportion the cold air leaving directly from the evaporator and the hot air having passed through the radiator 92. The hot flow and the cold stream mix again in a mixing chamber 96.

Line 82, shown in solid lines, is connected to the housing 88 of the heating appliance in a position between the evaporator 90 and the radiator 92. Line 82 therefore makes it possible to take cold air which is sucked in by the blower 14 of the ventilation device 2 to be blown, as described above, into the pockets of the seat 12. The flow of cold air taken downstream of the evaporator 90 can also be mixed in variable proportion with a flow of hot air produced by the heating resistor 28, as described above. A mechanical adjustment device 98 makes it possible to adjust the position of the mixing flap 48.

In another embodiment, the ventilation module 2 is connected to the ventilation, heating and / or air conditioning apparatus 84 by a pipe 102, shown in dotted lines in FIG. 8, which opens into the mixing chamber 96. This takes air at an adjustable temperature instead of taking cold air.

FIG. 9 shows a variant of the module of FIG. 8. This module comprises two heating resistors 28, one for each of the seats 12. The power of these resistors is, in the example, 300 watts. They are not graduated. They work in all or nothing. The air passing through the filter 26, as shown by the arrow 104, is distributed between the left compartment and the right compartment of the module. In addition, in the same way as for the variant of FIG. 8, a pipe 82 is connected to the air conditioning heating appliance 84 of the vehicle, just downstream of the evaporator 90 so as to draw cold air . The cold air supply line 82 splits in two so as to supply the left and right parts of the ventilation module. The module comprises a right mixing flap 106 adjustable by a mechanical control device 108 shown diagrammatically by a rectangle in FIG. 8 and a left mixing flap 110 adjustable separately from the previous one by a mechanical control device 112, also shown diagrammatically by a rectangle. The blower 114 of the module comprises a right wheel or propeller 116 and a left wheel or propeller 118. This module thus makes it possible to ventilate the left seat and the right seat separately, the adjustment of each of the parts of the device being separate.

In another variant, as illustrated in FIG. 13, provision can be made for the integration of an electronic card 220 in the second air passage 46. The electronic card 220 allows in particular the management of the position of the mixing flap 48, the control of the heating means 28, and the variation of the speed of the blower 14. The electronic card 220 can also integrate the means for controlling the devices 108 and 112.

This card is in electrical connection with the seat harness and thus receives the control information from the seat ventilation module. The card 220 is also provided with a probe which allows it to calculate the pressure of the air in the air passage 46. The card 220 being in an air passage, it is cooled by it, while being close to the elements it controls, which reduces connection problems.

The card 220 is provided with a computer. In operation, the computer receives in particular information on the operation of the blower such as the speed of rotation, the voltage and the supply current. This information is used to detect a leak and / or improper connection of the air channel.

Indeed, depending on the desired flow, the computer can determine the theoretical equivalent speed of the blower. By comparing it to the actual speed of rotation of the blower, it can be estimated whether there is a leak and / or a bad connection. In practice, the tolerance is fixed at more or less 500 revolutions per minute of difference with the theoretical speed.

Similarly, the intensity of the motor can be determined to determine if there is a leak and / or a bad connection. As the motor supply is proportional to the theoretical flow rate, the intensity it consumes can be monitored, by setting the tolerance at plus or minus 0.5 A.

So when the tolerance is exceeded in terms of number of revolutions per minute or supply intensity, the computer detects a leak and / or a bad connection and it sends a message to the maintenance operator who can act knowingly.

The card 220 can also be integrated in the air passage 6 as illustrated in FIG. 12, or in the air intake pipe 82 as illustrated in FIG. 14.

This module can be placed in the central console and connected to each of the seats by a deformable conduit.

Claims

claims

1. Seat ventilation module, in particular for a motor vehicle, characterized in that it comprises a housing (4), at least one air passage (6) arranged in the housing to circulate an air flow in the housing (4), a seat air passage (8) for circulating air through at least one seat (12), heating means (28) in the air passage, an air blower (14) for circulating an air flow between the seat air passage (8) and the air passage (6).

2. Module according to claim 1, characterized in that it comprises at least a second air passage (46) for circulating in the housing (4) a second air flow, a mixing flap (48) suitable moving between a first position in which it closes the first air passage and a second position in which it closes the second air passage (46) to mix in variable proportions the first and the second air flow.

3. Module according to one of claims 1 or 2, characterized in that the blower (14) is capable of blowing or sucking a flow of air through the seat (12).

4. Module according to claim 1 or 2, characterized in that the blower (14) is disposed in a conduit (58) having first and second ends (60, 62), a first flap (64) being disposed at the first end of the conduit

(58) and a second flap (68) being disposed at its second end, the first and the second flaps being designed so as to put the first and the second ends of the duct (58) in communication either with the air passage of seat (8), or with the air passage (6, 46).

5. Module according to one of claims 1 to 4, characterized in that the second air passage (46) is connected by a air intake duct (82) to the vehicle ventilation, heating and / or air conditioning apparatus (84).

6. Module according to claim 5, characterized in that the line (82) of air intake is connected to the ventilation, heating and / or air conditioning of the vehicle (84) at the outlet of a evaporator (90) housed in this device,

7. Module according to claim 5, characterized in that the air intake pipe (82) is connected to a mixing chamber (96) of the ventilation, heating and / or air conditioning device (84) of the vehicle.

8. Module according to one of claims 1 to 7, characterized in that the seat comprises an evacuation passage (200).

9. Module according to claim 8, characterized in that the seat has an evacuation flap (202) provided for closing the evacuation passage (200).

10. Module according to one of claims 8 and 9, characterized in that the seat comprises an air inlet passage (204).

11. Module according to claim 10, characterized in that the seat comprises an air inlet flap (206) for closing the air inlet passage (204).

12. Module according to one of claims 10 and 11, characterized in that, in a phase of operation of the module, the blower (14) is connected to the inlet passage (204), thereby circulating the air in the seat (12), this air being evacuated from the seat (12) by the evacuation passage (200), the evacuation flap (202) being provided to close the evacuation passage (200) during operation module normal.

13. Module according to claim 12, characterized in that the air blown into the seat (12) is recirculated air and / or taken downstream and / or upstream of the heating means (28).

14. Module according to one of claims 1 to 13, characterized in that it is mounted on the vehicle floor (80), a deformable conduit (10) connecting the seat air passage (8) to a minus a seat (12).

15. Module according to one of claims 1 to 13, characterized in that it is mounted directly under the seat of a seat (12) of the vehicle.

16. Module according to one of claims 1 to 13, characterized in that it is placed in the central console of the vehicle and connected by a left seat duct to the left seat and by a right seat duct to the right seat of the vehicle .

17. Module according to one of claims 1 to 16, characterized in that it is divided into a right part and a left part for the separate ventilation of the right seat and the left seat, each of the right and left parts comprising means (108; 112) independent adjustment.

18. Module according to one of claims 1 to 17, characterized in that the heating means (28) are electrical resistors with positive temperature coefficient.

19. Module according to one of claims 1 to 18, characterized in that it comprises an electronic card (220) for managing the module, located in the air passage (6).

20. Module according to one of claims 2 to 18, characterized in that it comprises an electronic card (220) for managing the module, located in the second air passage (46).

21. Module according to one of claims 5 to 18, characterized in that it comprises an electronic card (220) for managing the module, located in the air intake pipe (82).

22. Module according to one of claims 19 to 21, characterized in that the electronic card (220) comprises means for calculating leak detection.