JP2019131040A - Thermal insulation structure for cab - Google Patents

Abstract

To optimally block heat transmission from an engine side to a cab side.SOLUTION: A floor panel 11 is disposed above an engine room 4. A coupling panel 21 is integrally provided on a rail front panel part 16 of a rear mount rail 13 of the floor panel 11. A bracket 31 is fixed to the coupling panel 21. A bolt insertion hole 40 is formed in a lower area 37 of the bracket 31. A clip locking hole 41 is formed in an upper area 38. The clip locking hole 41 is disposed at a position rearward apart from an upper area 43 of the rail front part 16. A second insulator 32 is fixed to the clip locking hole 41 of the bracket 31 and covers the upper area 43 of the rail front plate part 16 at a position rearward apart from the upper area 43 of the rail front plate part 16.SELECTED DRAWING: Figure 3

Description

  The present disclosure relates to a heat insulating structure of a cab.

  Patent Document 1 describes a mounting structure for a floor insulator that is mounted on the lower surface of a cab floor of a cab-over type vehicle. The floor insulator is a well-known heat-absorbing sound absorbing material made of glass wool or other material that blocks noise and heat from the engine. And is assembled to the lower surface of the cab floor with plastic screws.

JP 2011-126308 A

  In the floor insulator mounting structure described in Patent Document 1, a floor insulator formed in accordance with the shape of the lower surface of the cab floor is fixed to the lower surface of the cab floor to block heat from the engine. However, if the floor insulator mounting structure described in Patent Document 1 is applied to a vehicle having an engine that generates higher-temperature heat, the heat from the engine side may not be sufficiently shielded.

  In view of the above, an object of the present disclosure is to provide a heat insulating structure for a cab capable of suitably blocking heat transfer from the engine side to the cab side.

  In order to solve the above-mentioned problem, a first aspect of the present invention is a heat insulating structure for a cab that suppresses heat transfer from the engine side to the cab side of a cab-over type vehicle in which the engine is disposed below the cab. A cab panel, a bracket, and a heat shield member are provided. The cab panel is disposed above the engine room that houses the engine. The bracket includes a cab side fixing portion that is fixed to the cab panel, and a heat shield member fixing portion that is disposed at a position separated from a partial region of the cab panel. The heat shield member has a supported part that is fixed to the heat shield member fixing part of the bracket and supported by the bracket, and is spaced apart from the partial area of the cab panel and between the partial area. In a state where the space is partitioned, at least a part of the region is covered from the engine room side to suppress the transfer of heat from the engine side to the cab panel side.

  In the above configuration, the heat shield member is separated from the partial area of the cab panel and divides a space between the partial area, and therefore, the partial area of the cab panel and the heat shield member are separated from each other. An air layer can be provided between them. The heat shield member covers the partial area of the cab panel from the engine room side and suppresses heat transfer from the engine side to the cab panel side. As described above, since not only the heat shield member but also the air layer is provided between the partial area of the cab panel and the engine, the engine area is connected to the partial area (cab side) of the cab panel. Heat transfer can be suitably suppressed by both the heat shield member and the air layer.

  Further, since the heat shield member fixing portion of the bracket is disposed at a position away from the partial area of the cab panel, the heat shield member and the cab panel can be shielded only by fixing the heat shield member to the heat shield member fixing portion of the bracket. An air layer can be easily provided between the heat member. Therefore, heat transfer from the engine side to the cab side can be suitably suppressed with a simple structure.

  According to a second aspect of the present invention, there is provided the cab heat insulating structure according to the first aspect, wherein the heat insulating member has a plurality of supported portions. A plurality of brackets are provided so as to correspond to a plurality of supported portions of the heat shield member, and are respectively fixed to the cab panel.

  In the above configuration, the heat shield member has a plurality of supported portions, and a plurality of brackets are provided so as to correspond to the plurality of supported portions of the heat shield member, and are respectively fixed to the cab panel. That is, since separate brackets are provided for the plurality of supported portions of the heat shield member, for example, one bracket is provided for the plurality of supported portions of the heat shield member that are separated from each other in the vehicle width direction. Unlike the case, the heat shield member can be fixed to the cab panel by a plurality of small brackets. As described above, since the increase in size of the bracket can be suppressed, when the heat shield member is fixed to the cab panel using the metal bracket, the heat shield member is transmitted to the cab panel side through the bracket. Heat. For this reason, heat transfer from the engine side to the cab side can be suppressed.

  According to a third aspect of the present invention, there is provided a cab heat-insulating structure according to the first aspect or the second aspect, wherein the cab panel crosses the front-rear direction at the rear end lower portion of the cab. A panel rear surface portion extending in the direction. The partial area of the cab panel is included in the panel rear surface. The panel rear surface portion has a bracket fixing portion that is disposed below and behind the partial area and to which the cab side fixing portion of the bracket is fixed. A bracket has a connection part extended in the up-down direction substantially linearly between the cab side fixing | fixed part and the heat shield member fixing | fixed part. The heat shield member fixing portion of the bracket is disposed above the cab side fixing portion and is disposed at a position spaced rearward from the partial area of the panel rear surface portion. The heat shield member fixed to the cab panel is spaced rearward from the partial area of the cab panel.

  In the above configuration, the panel rear surface portion of the cab panel extending in the vehicle width direction in a state of crossing the front and rear direction at the lower rear end of the cab includes the partial area of the cab panel (area covered by the heat shield member), The heat shield member is spaced rearward from the partial area of the cab panel. Therefore, the heat transfer from the engine side to the panel rear surface at the lower rear end of the cab can be suitably suppressed by both the heat shield member and the air layer.

  In addition, since the bracket fixing portion on the rear surface of the panel is disposed behind the partial area of the rear surface of the panel, a substantially straight line is formed between the bracket's cab side fixing portion and the heat shield member fixing portion in the vertical direction. By using a bracket having a simple structure provided with a connecting portion extending in a shape, the heat shield member fixing portion of the bracket can be easily disposed at a position spaced rearward from the partial region of the cab panel. For this reason, it is possible to suppress heat transfer from the engine side to the partial area (cab side) of the cab panel with a simple structure.

  According to a fourth aspect of the present invention, there is provided the heat insulating structure for a cab according to the third aspect, wherein the heat insulating member is disposed behind the bracket and covers the bracket from the rear.

  In the above configuration, the heat shield member is disposed behind the bracket and covers the bracket from the rear. For this reason, since heat from the engine side can be suppressed by the heat shield member from being transmitted from the rear to the cab side fixing portion of the bracket, the transmission of heat from the engine side to the cab side is suitably suppressed. can do.

  According to the present disclosure, heat transfer from the engine side to the cab side can be suitably shielded.

It is a schematic perspective view from the back of the cab to which the heat insulation structure concerning this embodiment is applied. It is II-II arrow sectional drawing of FIG. It is an enlarged view of the principal part of FIG. It is an exploded view of the heat insulation structure of FIG. It is a perspective view of a bracket, (a) shows the state seen from the upper side outside the vehicle width direction, and (b) shows the state seen from the upper side inside the vehicle width direction. It is a schematic sectional drawing which concerns on other embodiment, (a) shows the state which the rail front board part protruded back, (b) shows the state which the bracket protruded back, respectively.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In each figure, FR indicates the front of the vehicle, UP indicates the upper side, and IN indicates the inner side in the vehicle width direction. Moreover, in the following description, the left-right direction means the left-right direction with the vehicle facing forward.

  As shown in FIG. 1, the heat shield structure according to the present embodiment is applied to a cab-over type vehicle 1 in which the engine 2 is disposed below the cab 3, and transfers heat from the engine 2 side to the cab 3 side. Suppress. The engine 2 is housed in the engine room 4 below the cab 3. The engine 2 side includes not only the engine 2 but also parts that are arranged in the engine room 4 and generate heat as the engine 2 is driven, such as an intake pipe and an exhaust pipe connected to the engine 2. included.

  As shown in FIGS. 1 and 2, the cab 3 includes a floor panel (cab panel) 11 that defines a lower part of a cabin 5 inside the cab 3, and a back panel 12 that defines the rear of the cabin 5. . The rear end side of the floor panel 11 and the lower end side of the back panel 12 are fixed to each other. A pair of left and right rear cab mount brackets 6 are fixed to both sides in the vehicle width direction at the lower rear end of the cab 3. The rear end side of the cab 3 is supported from below by a vehicle body frame (not shown) via left and right rear cab mount brackets 6.

  The floor panel 11 is a panel (cab panel) constituting the outer surface (lower surface) of the cab 3 and is disposed above the engine room 4. The floor panel 11 includes a rear mount rail 13 that extends in the vehicle width direction with the rear end opened downward, a rear region 17 that bends from the front end edge of the rear mount rail 13 and extends forward and intersects with the vertical direction. A step 18 that is bent from the front edge of the rear region 17 and extends downward and intersects with the front-rear direction; and a front region 19 that is bent from the lower edge of the step 18 and extends forward and intersects with the vertical direction. Have. The rear region 17 is disposed above the engine 2. A first insulator 20 made of a material having a heat shielding performance such as glass wool is fixed to the lower surface of the rear region 17. The first insulator 20 suppresses heat transfer from the engine 2 side to the rear region 17 (cab 3 side) of the floor panel 11.

  As shown in FIGS. 2 and 3, the rear mount rail 13 includes a back panel joint portion 14, a rail upper plate portion 15, and a rail front plate portion (panel rear surface portion) 16 disposed above the engine room 4. Then, it extends in the vehicle width direction of the cab 3 at the lower portion of the rear end of the cab 3 to ensure the rigidity of the rear end portion of the floor panel 11. The back panel joint portion 14 extends in the vehicle width direction while intersecting with the front-rear direction, and is fixed in a state where the front surface of the lower end edge portion 12a of the back panel 12 is in surface contact with the rear surface. The rail upper plate portion 15 bends forward from the upper end edge of the back panel joint portion 14 (corner portion 53 between the back panel joint portion 14 and the rail upper plate portion 15), and crosses in the vertical direction. The rail front plate portion 16 is bent downward from the front end edge (the corner portion 30 between the rail front plate portion 16 and the rail upper plate portion 15) of the rail upper plate portion 15 and below the lower end edge of the back panel joint portion 14. It extends to and intersects with the front-rear direction. That is, the rail front plate portion 16 extends in the vehicle width direction in a state of crossing the front-rear direction at the rear end lower portion of the cab 3. The rail front plate portion 16 includes a vertical portion 16a extending in a substantially vertical direction from the front end edge of the rail upper plate portion 15 to a position below the lower end edge of the back panel joint portion 14, and a vertical direction from the lower end edge of the vertical portion 16a. And an inclined portion 16b extending downward and forward in an inclined state. The front surface of the back panel joint portion 14, the lower surface of the rail upper plate portion 15, and the rear surface of the rail front plate portion 16 define a space in which a cab mount assembly 7 described later can be disposed. A cab mount assembly 7 is disposed in the space, and the cab mount assembly 7 is fixed to the rear mount rail 13. The rear region 17 of the floor panel 11 is bent from the lower end edge of the inclined portion 16b of the rail front plate portion 16 and extends forward.

  The cab mount assembly 7 includes a left and right rear cab mount bracket 6 and a connecting panel 21 extending in the vehicle width direction between the left and right rear cab mount brackets 6 and is fixed to the rear mount rail 13. Both ends of the connection panel 21 in the vehicle width direction are fixed to the left and right rear cab mount brackets 6.

  The connection panel 21 is formed by bending a plate, is fixed to the rail front plate portion 16 of the rear mount rail 13 by welding, and reinforces the rear mount rail 13 between the left and right rear cab mount brackets 6. In a state where the cab mount assembly 7 is fixed to the rear mount rail 13, the connection panel 21 is provided integrally with the rail front plate portion 16 of the rear mount rail 13 and constitutes a part of the floor panel 11. That is, the rail front plate part 16 has the connection panel 21. The connection panel 21 integrally includes a lower plate portion 22, a rear plate portion 23, and an upper plate portion 24, and extends between the left and right rear cab mount brackets 6 in the vehicle width direction. A closed space 54 is defined between the connection panel 21 and the rail front plate portion 16. The lower plate portion 22 is fixed to the lower surface of the inclined portion 16b of the rail front plate portion 16 and extends rearward and upward along the inclined portion 16b. The front lower end portion 25 of the lower plate portion 22 is fixed to the lower surface of the inclined portion 16b of the rail front plate portion 16, and the rear upper end edge 26 of the lower plate portion 22 is the upper end edge of the inclined portion 16b of the rail front plate portion 16 ( It is disposed rearward and upper than the corner portion 27) of the vertical portion 16a and the inclined portion 16b and forward of the back panel joint portion 14 of the rear mount rail 13. The rear plate portion 23 bends upward from the rear upper edge 26 of the lower plate portion 22 and faces the rear surface of the vertical portion 16a of the rail front plate portion 16 from the rear. The upper end edge 28 of the rear plate portion 23 is disposed at a position spaced downward from the lower surface of the rail upper plate portion 15. The upper plate portion 24 extends from the upper end edge 28 of the rear plate portion 23 toward the front upper side to the rear surface of the vertical portion 16a of the rail front plate portion 16 and is fixed to the vertical portion 16a of the rail front plate portion 16. . The front end edge 29 of the upper plate portion 24 is disposed at a position spaced downward from the upper end edge (corner portion 30) of the rail front plate portion 16.

  As shown in FIGS. 3, 4, 5 (a), and 5 (b), the rear plate portion 23 of the connection panel 21 includes a plurality of (three in the present embodiment) bracket fixing portions 39. A pair of left and right clip locking holes 44 are provided. That is, the bracket fixing portion 39 is a partial region of the rail front plate portion 16 of the rear mount rail 13 (in this embodiment, the front end edge 29 of the upper plate portion 24 of the connection panel 21 in the rail front plate portion 16). It is arranged below and behind the upper region 43). Each bracket fixing portion 39 is configured by a bolt insertion hole 45 penetrating the rear plate portion 23 in the front-rear direction and a nut 46 fixed to the front surface of the rear plate portion 23. The inner diameter portion of the nut 46 communicates with the bolt insertion hole 45. The plurality of bracket fixing portions 39 include a middle bracket fixing portion 39a disposed at a center portion in the vehicle width direction, and spaced apart from the middle bracket fixing portion 39a on both sides in the vehicle width direction from the left and right rear cab mount brackets 6 in the vehicle width direction. Left and right bracket fixing portions 39b and 39c arranged at positions spaced inward. The left and right clip locking holes 44 are disposed below the left and right bracket fixing portions 39b and 39c and on the outer side in the vehicle width direction, and penetrate the rear plate portion 23 in the front-rear direction. A plurality of (three in this embodiment) brackets 31 are fixed to the plurality of bracket fixing portions 39, and a second insulator (heat insulating member) 32 is fixed to the plurality of brackets 31. That is, the second insulator 32 is fixed to the rear plate portion 23 of the connection panel 21 via the plurality of brackets 31.

  The plurality of brackets 31 include a middle bracket 31a fixed to the middle bracket fixing portion 39a in the rear plate portion 23 of the connection panel 21, and left and right bracket fixing portions 39b and 39c spaced from the middle bracket 31a on both sides in the vehicle width direction. The left and right brackets 31b and 31c are fixed to each other. The plurality of brackets 31 are disposed at substantially the same height positions, and are fastened and fixed to the rear plate portion 23 of the connection panel 21 by bolts 33. The number of the bracket fixing portions 39 and the brackets 31 provided on the rear plate portion 23 of the connection panel 21 is the same as the number of the upper clip insertion holes 48 of the second insulator 32 described later. 5A and 5B show the middle bracket 31a and the left bracket 31b, and the right bracket 31c is not shown.

  The plurality of brackets 31 are formed on the upper surface of the upper plate portion 24 of the connecting panel 21 and the flat plate portion 34 that extends substantially linearly in the vertical direction along the rear surface of the rear plate portion 23 of the connecting panel 21 in a state of crossing the front and rear direction. This is a metal bracket 31 having a pair of left and right engaging plate portions 35 that abut and a reinforcing plate portion 36 that reinforces the upper portion of the flat plate portion 34. The flat plate portion 34 includes a lower region 37 that is in surface contact with the rear surface of the rear plate portion 23 of the connection panel 21, and an upper region 38 that extends linearly upward from the lower region 37. The lower region 37 of the flat plate portion 34 is formed wider on both sides in the vehicle width direction than the upper region 38. A bolt insertion hole (cab side fixing portion) 40 that penetrates in the front-rear direction and allows the bolt 33 to be inserted is formed in the lower region 37 of the flat plate portion 34. The upper region 38 of the flat plate portion 34 extends substantially linearly upward from a substantially central portion in the vehicle width direction of the upper end edge of the lower region 37, and is an upper region (partial region) of the rail front plate portion 16 of the rear mount rail 13. ) It is arranged at a position spaced rearward from 43. In an upper region 38 of the flat plate portion 34, a clip locking hole (heat shield member fixing portion) 41 penetrating in the front-rear direction is formed. That is, the clip locking hole 41 is disposed at a position spaced rearward from the upper region 43 of the rail front plate portion 16 of the rear mount rail 13. A region 42 between the bolt insertion hole 40 and the clip locking hole 41 in the flat plate portion 34 extends substantially linearly in the vertical direction, and serves as a connecting portion that connects the bolt insertion hole 40 and the clip locking hole 41. Function. The left and right locking plate portions 35 bend forward from the regions on both sides in the vehicle width direction of the upper region 38 in the upper end edge of the lower region 37 of the flat plate portion 34 and cross the upper and lower directions. The reinforcing plate portion 36 bends from the edge of one side (right side in the present embodiment) of the upper region 38 of the flat plate portion 34 in the vehicle width direction and extends forward.

  As shown in FIGS. 3 and 4, the second insulator 32 is a plate that covers the connection panel 21 and the upper region 43 of the rail front plate portion 16 of the rear mount rail 13 from behind and covers the rail upper plate portion 15 from below. It is a shape-like member, and is formed of a material having a heat shielding performance such as glass wool. The second insulator 32 extends in the vehicle width direction in a state of crossing with the front-rear direction, and both ends of the second insulator 32 in the vehicle width direction are disposed in the vicinity of the left and right rear cab mount brackets 6. The second insulator 32 includes a pair of left and right lower clip insertion holes 47 disposed at positions corresponding to the left and right clip locking holes 44 of the rear plate portion 23 of the connection panel 21, and clip locking holes of the plurality of brackets 31. And a plurality (three in this embodiment) of upper clip insertion holes (supported portions) 48 arranged at positions corresponding to 41. The left and right lower clip insertion holes 47 of the second insulator 32 are locked and fixed by clips 49 to the left and right clip locking holes 44 of the rear plate portion 23 of the connection panel 21, and a plurality of upper clips of the second insulator 32 are fixed. The insertion hole 48 is locked and fixed to the clip locking holes 41 of the plurality of brackets 31 by clips 49. The lower end portion 32 a of the second insulator 32 is in contact with or close to the lower surface on the rear upper side of the lower plate portion 22 of the connection panel 21. The upper end 32b of the second insulator 32 extends rearward and upward from substantially the same height as the upper end of the bracket 31, and the tip of the upper end 32b (the rear upper end edge of the second insulator 32) is the back panel of the rear mount rail 13. It arrange | positions in the vicinity of the corner | angular part 53 of the junction part 14 and the rail upper board part 15. FIG. That is, the second insulator 32 extends in the vertical direction between the lower plate portion 22 of the connection panel 21 and the rail upper plate portion 15. The second insulator 32 covers the entire rear surface of the plurality of brackets 31 from the rear. Of the second insulator 32, the upper region 50 disposed above the upper end edge 28 of the rear plate portion 23 of the connection panel 21 is spaced rearward from the upper region 43 of the rail front plate portion 16 of the rear mount rail 13. A space 51 is defined between the rail front plate portion 16 and the upper region 43 of the rail front plate portion 16 so as to face the upper region 43 of the rail front plate portion 16. The space 51 is also a space 51 between the second insulator 32 and the rail upper plate portion 15.

  In the vehicle 1 configured as described above, the upper region 50 of the second insulator 32 is spaced rearward from the upper region 43 of the rail front plate portion 16 and between the upper region 43 of the rail front plate portion 16. Since the space 51 is partitioned, an air layer (an air layer in the space 51) can be provided between the upper region 43 of the rail front plate portion 16 and the second insulator 32. The second insulator 32 is formed of a material having a heat shielding performance such as glass wool, covers the upper region 43 of the rail front plate portion 16 of the rear mount rail 13 from the rear, and extends from the engine 2 side to the floor panel 11 side. Suppresses heat transfer. Thus, since not only the second insulator 32 but also an air layer is provided between the engine 2 and a partial region of the floor panel 11 (upper region 43 of the rail front plate portion 16), the engine 2 side Heat transfer to the cab 3 side (upper region 43 side of the rail front plate portion 16 of the floor panel 11) can be suitably suppressed by both the second insulator 32 and the air layer.

  The second insulator 32 covers the rail upper plate portion 15 from below in a state where the space 51 is partitioned between the second insulator 32 and the rail upper plate portion 15. For this reason, heat transmission from the engine 2 side to the cab 3 side (the rail upper plate portion 15 side of the floor panel 11) is suitably suppressed by both the second insulator 32 and the air layer (the air layer in the space 51). be able to.

  The second insulator 32 covers the connection panel 21 of the cab mount assembly 7 from the rear. For this reason, the heat transmission from the engine 2 side to the cab 3 side (the connection panel 21 side of the floor panel 11) can be suppressed by the second insulator 32.

  Moreover, the 2nd insulator 32 covers the whole rear surface of the some bracket 31 from back. That is, since the plurality of brackets 31 are covered with the second insulator 32 and are not exposed to the engine room 4, heat transfer from the engine 2 side to the bracket 31 can be suppressed by the second insulator 32. Therefore, heat transfer from the bracket 31 to the cab 3 side can be suppressed, and heat transfer from the engine 2 side to the cab 3 side can be suitably suppressed by the second insulator 32.

  The second insulator 32 has a plurality of upper clip insertion holes 48, and a plurality of brackets 31 are provided so as to correspond to the number of the upper clip insertion holes 48 of the second insulator 32, and Fixed respectively. That is, since the separate brackets 31 are provided for the plurality of upper clip insertion holes 48 of the second insulator 32, a single bracket having a plurality of clip locking holes (heat shield member fixing portions) 41 is provided. Unlike the above, the second insulator 32 can be fixed to the floor panel 11 by a plurality of small brackets 31. Thus, since the enlargement of the bracket 31 can be suppressed, even if the second insulator 32 is fixed to the floor panel 11 using the metal bracket 31, the bracket 31 is interposed from the second insulator 32. The heat transmitted to the floor panel 11 side can be suppressed. For this reason, heat transfer from the engine 2 side to the cab 3 side can be suppressed.

  Further, the upper region 38 of the flat plate portion 34 of the bracket 31 is disposed at a position spaced rearward from the upper region 43 of the rail front plate portion 16 of the rear mount rail 13, and the clip locking hole 41 is formed in the upper region 38 of the bracket 31. Is formed. For this reason, an air layer can be easily provided between the rail front plate portion 16 and the second insulator 32 only by fixing the second insulator 32 to the clip locking hole 41 of the bracket 31. Therefore, heat transfer from the engine 2 side to the cab 3 side can be suitably suppressed with a simple structure.

  Further, since the rear plate portion 23 of the connection panel 21 fixedly provided on the rail front plate portion 16 is arranged behind the upper region 43 of the rail front plate portion 16, the flat plate portion extending linearly in the vertical direction. By using the bracket 31 having a simple structure having 34, the clip locking hole 41 in the upper region 38 of the bracket 31 can be easily arranged at a position spaced rearward from the upper region 43 of the rail front plate portion 16. it can. For this reason, heat transfer from the engine 2 side to the cab 3 side can be suppressed with a simple structure.

  Therefore, according to the present embodiment, heat transfer from the engine 2 side to the cab 3 side can be suitably interrupted.

  In the present embodiment, the second insulator 32 that covers the entire rear surface of the bracket 31 from the rear is provided, but the second insulator (heat shield member) 32 is not limited to this. For example, the heat shield member may be disposed above the lower region 37 of the bracket 31 so that the heat shield member covers only the upper region 38 of the bracket 31 from the rear. In the present embodiment, the second insulator (heat shield member) 32 is disposed behind the bracket 31, but the heat shield member may be disposed in front of the upper region 38 of the bracket 31.

  Moreover, in this embodiment, although the 2nd insulator 32 was fixed with respect to the floor panel 11 using the some bracket 31 corresponding to the some upper clip penetration hole 48 of the 2nd insulator 32, it is limited to this. is not. For example, the second insulator 32 is fixed to the floor panel 11 using one bracket having a plurality of clip locking holes (heat shield member fixing portions) with respect to the plurality of upper clip insertion holes 48 of the second insulator 32. Alternatively, one upper clip insertion hole 48 may be provided in the second insulator 32 and the second insulator 32 may be fixed to the floor panel 11 using one bracket.

  Further, in this embodiment, the upper insulator 32 is provided with an upper clip insertion hole (supported portion) 48, and the second insulator 32 is connected to the clip locking hole (heat shield member fixing portion) 41 of the bracket 31 via the clip 49. However, the method of fixing the second insulator 32 to the bracket 31 is not limited to clip fastening, and various methods can be used. That is, the supported portion of the second insulator 32 is not limited to the clip insertion hole, and the heat shield member fixing portion of the bracket 31 is not limited to the clip locking hole.

  In the present embodiment, the bracket 31 is provided with a bolt insertion hole (cab side fixing portion) 40, the connection panel 21 is provided with a bracket fixing portion 39 including a bolt insertion hole 45 and a nut 46, and the bracket 31 is bolted Although it fixed to the connection panel 21 side (cab 3 side) 33, the fixing method of the bracket 31 to the cab 3 side is not limited to this, Various methods can be used. That is, the cab side fixing portion of the bracket 31 is not limited to the bolt insertion hole, and the bracket fixing portion 39 of the connection panel 21 is not limited to the bolt insertion hole 45 and the nut 46.

  In the present embodiment, the metal bracket 31 is provided, but the bracket 31 is not limited to metal.

  Moreover, in this embodiment, although the connection panel 21 was fixedly provided with respect to the rail front board part 16 of the rear mount rail 13, it is not limited to this, For example, as shown to Fig.6 (a) In addition, a protruding portion 61 that protrudes rearward may be provided at the lower portion of the rail front plate portion 16, and a bracket fixing portion 63 such as a bolt insertion hole may be provided on the rear plate portion 62 of the protruding portion 61. In this case, the rear plate portion 62 of the protruding portion 61 is disposed behind the partial region of the rail front plate portion 16 (the region 72 above the protruding portion 61). Alternatively, as shown in FIG. 6B, a bracket fixing portion 65 such as a bolt insertion hole is provided at the lower portion of the rail front plate portion 16 extending linearly in the vertical direction, and the bracket 66 bent in a crank shape is bracketed. You may fix to the fixing | fixed part 65. FIG. The bracket 66 includes a lower region 68 in which a bolt insertion hole (cab side fixing portion) 67 is formed, an upper region 70 in which a clip locking hole (heat shield member fixing portion) 69 is formed, a lower region 68 and an upper region. 70 and an intermediate region 71 that connects to 70. The upper region 70 of the bracket 66 is disposed rearward of the lower region 68 and is spaced rearward from a partial region of the rail front plate portion 16 (region 73 above the lower region 68 of the bracket 66).

  In the present embodiment, the rear end portion of the floor panel 11 constitutes the rear mount rail 13, but the lower end portion of the back panel 12 may constitute the rear mount rail 13. In this case, the back panel 12 becomes a cab panel.

  As mentioned above, although this indication was demonstrated based on the said embodiment, this indication is not limited to the content of the said embodiment, Of course, it can change suitably in the range which does not deviate from this indication. That is, it is needless to say that other embodiments, examples, operational techniques, and the like made by those skilled in the art based on this embodiment are all included in the scope of the present disclosure.

  For example, in the above-described embodiment, the heat insulating structure of the cab according to the present disclosure suppresses heat transmission to a partial region 43 of the rail front plate portion (panel rear surface portion) 16 of the rear mount rail 13 of the floor panel 11. Although applied to the structure, the present invention is not limited to this, and is disposed above the engine room 4 to suppress heat transfer to a partial region of a panel (cab panel) constituting the outer surface of the cab 3. Can be applied to the structure. For example, a bracket for fixing the first insulator 20 is fixed to the lower surface of the rear region 17 of the floor panel 11, and the heat shielding member fixing portion of the bracket is spaced downward from the lower surface of the rear region 17 of the floor panel 11. The first insulator 20 disposed and fixed to the heat shield fixing part of the bracket covers a part of the rear area 17 of the floor panel 11 from below, and a space is formed between the part and the part. You may partition.

  The heat insulating structure of the cab according to the present disclosure can be widely applied to a cab over type vehicle in which an engine is mounted below the cab.

1: Vehicle 2: Engine 3: Cab 4: Engine room 11: Floor panel (cab panel)
16: Rail front plate (panel rear)
31, 66: Bracket 32: Second insulator (heat shield member)
39, 63, 65: Bracket fixing part 40, 67: Bolt insertion hole (cab side fixing part)
41, 69: Clip locking hole (heat shield member fixing part)
42: Area between the bolt insertion hole and the clip locking hole (connection portion)
43: Upper region of rail front plate (partial region)
48: Upper clip insertion hole (supported part)
51: Space 72, 73: Partial region of rail front plate

Claims (4)

A heat insulating structure of a cab that suppresses heat transfer from the engine side to the cab side of a cab over type vehicle in which an engine is disposed below the cab,
A cab panel disposed above an engine room that houses the engine;
A bracket having a cab side fixing portion fixed to the cab panel, and a heat shield member fixing portion arranged at a position separated from a partial region of the cab panel;
A supported portion fixed to the bracket and supported by the bracket and spaced from the partial area of the cab panel and between the partial area; A heat shield member that covers at least a part of the region from the engine room side in a state of partitioning the space and suppresses heat transfer from the engine side to the cab panel side. Heat insulation structure of the cab. The cab heat shield structure according to claim 1,
The heat shield member has a plurality of the supported parts,
A plurality of the brackets are provided so as to correspond to the plurality of supported portions of the heat shield member, and are respectively fixed to the cab panel. The heat insulating structure for a cab according to claim 1 or 2,
The cab panel has a panel rear surface portion that extends in the vehicle width direction in a state crossed with the front-rear direction at the lower rear end of the cab,
The partial area of the cab panel is included in the panel rear surface portion,
The panel rear surface portion has a bracket fixing portion that is disposed below and behind the partial region and to which the cab side fixing portion of the bracket is fixed,
The bracket has a connecting portion extending substantially linearly in the vertical direction between the cab side fixing portion and the heat shield member fixing portion,
The heat shield member fixing portion of the bracket is disposed above the cab side fixing portion, and is disposed at a position spaced rearward from the partial region of the panel rear surface portion,
The heat insulating structure for a cab, wherein the heat insulating member fixed to the cab panel is spaced rearward from the partial area of the cab panel. The heat insulating structure for a cab according to claim 3,
The heat insulating structure for a cab, wherein the heat insulating member is disposed behind the bracket and covers the bracket from the rear.

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