ROOF ASSEMBLY FOR A CABIN OF AGRICULTURAL MACHINE HAVING AN AIR INLET SHIELD

Abstract

A roof assembly for a vehicle cabin, particularly for the cabin of an agricultural machine, comprising a housing of plastic material and an air conditioning unit housed within the housing, and at least one air inlet fluidically connected to the air conditioning unit and arranged at a periphery of the housing, and a filter arranged downstream of the air inlet. An air inlet shield is arranged at the air inlet, said air inlet shield being mounted to the periphery of the housing and sealingly mounted to the air inlet, the air inlet shield comprising a pair of shaped plates of plastic material, peripherally welded to each other, between which a chamber fluidically communicating with the filter and with the outside of the roof assembly is defined.

Claims

1. A roof assembly for a vehicle cabin, particularly for the cabin of an agricultural machine, comprising: a housing of plastic material and an air conditioning unit housed within the housing, and at least one air inlet fluidically connected to the air conditioning unit and arranged at a periphery of the housing, and a filter arranged downstream of the air inlet, wherein an air inlet shield is arranged at the air inlet, said air inlet shield being mounted to the periphery of the housing and sealingly mounted to the air inlet, said air inlet shield comprising a pair of shaped plates of plastic material, peripherally welded to each other and arranged upstream of the filter, between the plates there being defined a chamber fluidically communicating with the filter and with the outside of the roof assembly.

2. An assembly according to claim 1, wherein said air inlet shield has at least one inner window through which the chamber is fluidically communicating with the filter, and at least one outer window through which the chamber is fluidically communicating with the outside of the roof assembly, and wherein said air inlet shield defines an air inlet path from the outer window to the filter that has a non-rectilinear course.

3. An assembly according to claim 1, wherein said pair of plates comprises an inner plate sealingly mounted to the air inlet, and an outer plate peripherally welded to the inner plate.

4. An assembly according to claim 3, wherein the chamber of the air inlet shield fluidically communicates with the filter through at least one inner window formed through the inner plate.

5. An assembly according to claim 3, wherein the chamber of the air inlet shield fluidically communicates with the outside of the roof assembly through at least one outer window formed through the inner plate and/or the outer plate.

6. An assembly according to claim 1, wherein the chamber of the air inlet shield fluidically communicates with the outside of the roof assembly through at least one outer window formed on a downwardly facing lower part of the air inlet shield.

7. An assembly according to claim 6, wherein the air inlet shield forms a shield barrier downwardly extending past the outer window, said shield barrier being arranged at a more peripheral position than the outer window.

8. An assembly according to claim 5, wherein the outer window is formed on a downwardly facing lower part of the inner plate.

9. An assembly according to claim 8, wherein the air inlet shield forms a shield barrier downwardly extending past the outer window, said shield barrier being arranged at a more peripheral position than the outer window.

10. An assembly according to claim 9, wherein said shield barrier is formed by lower edges of the inner plate and outer plate welded to each other.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] Further features and advantages of the roof assembly according to the invention will become apparent from the following detailed description of an embodiment of the invention, made with reference to the accompanying drawings, provided for illustrative and non-limiting purposes only, in which:

[0013] FIG. 1 schematically shows a roof assembly according to the invention,

[0014] FIG. 2 is a schematic cross-sectional view of the roof assembly, and

[0015] FIG. 3 is an enlarged-scale view taken at an air inlet.

DETAILED DESCRIPTION

[0016] FIGS. 1 and 2 schematically represent a roof assembly for an agricultural machine cabin, conventionally comprising a plastic housing 10 and an air conditioning unit 20 housed inside the casing 10, as well as at least one air inlet 30 fluidically connected with the air conditioning unit 20 and located at the periphery of the casing 10. Through the air inlet 30, the air conditioning unit 20 conventionally draws air from outside and feeds it into the vehicle cabin, in a manner known per se, after having treated it.

[0017] Downstream of the air inlet 30 and upstream of the air conditioning unit 20, at least one filter 31 is arranged, conventionally provided for the removal of the contaminants from the air intended to be introduced into the cabin.

[0018] With reference to FIG. 3, at the air inlet 30 there is arranged an air inlet shield 40 mounted on the periphery of the casing 10, so as to be positioned tightly on the air inlet 30. In the illustrated example, the seal is obtained by a gasket 41, interposed between an edge of the air inlet 40 and the air inlet shield 40.

[0019] The air inlet shield 40 comprises a pair of shaped plates 42, 43 of plastic material, peripherally welded to each other, between which a chamber 44 fluidically communicating with the air inlet and with the outside of the roof assembly is defined. The shaped plates 42, 43 therefore form an inner wall and an outer wall, respectively, which enclose the chamber 44. The inner wall or plate 42 is sealably mounted on the edge of the air inlet 30, while the outer sheet or wall 43 is peripherally welded to the inner sheet or wall 42.

[0020] The air inlet shield 40 may be made by twin-sheet thermoforming. This technique conventionally provides that two separate sheets of plastic material are heated simultaneously. A sheet is pulled against a respective first die part and the other plate is pulled against a respective second die part by vacuum application. The two die parts are closed by pressing the two sheets against each other at their perimeter. Air (or other gaseous fluid) is then blown between the sheets, the pressure of which causes each of the sheets to conform to the shape of the respective die part. Finally, the result of the process is a structurally rigid hollow piece. Further processing is possible to obtain the final shape of the air inlet shield 40.

[0021] The air inlet shield 40 has at least one internal window 45, obtained in the inner sheet or wall 42, through which the chamber 44 is fluidically communicating with the filter 31. The air inlet shield 40 further comprises at least one external window 46, obtained in the inner sheet or wall 42 and/or in the outer sheet or wall 43, through which the chamber 44 is fluidly communicating with the exterior of the roof assembly. The air inlet shield 40 defines an air inlet path (represented by the arrows F in FIG. 3) from the external window 46 to the filter 31 which has a non-rectilinear course.

[0022] In the example shown, the chamber 44 of the air inlet shield 40 fluidically communicates with the outside of the roof assembly through at least one outer window 46 formed on a downwardly facing lower part of the air inlet shield 40, in particular on a lower part of the inner wall 42 facing downwards.

[0023] Furthermore, the air inlet shield 40 preferably forms a protective barrier 47 extending downwardly beyond the outer window 46. This barrier 47 provides a further obstacle to the penetration of water, particularly in the case of rain. The shield barrier 47 is arranged in a more peripheral position, i.e. more external than the outer window 46. Advantageously, the shield barrier 47 is formed by lower edges of the inner plate 42 and outer plate 43 welded to each other.