Hybrid single and double wall case

Abstract

A hybrid double and single wall case with two pivotally connected body portions which are single molded pieces that pivot between an open position and a closed position to respectively receive and contain a chainsaw. A portion of the body sections is configured as a double wall structure and a portion of one of the body sections is configured as a single wall structure.

Claims

1. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge wherein said first body section is a single molded piece and said second body section is another single molded piece; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of the first body section being configured as a double wall structure; a portion of the first body section being configured as a single wall structure; a portion of the second body section being configured as a double wall structure; and a portion of the second body section being configured as a single wall structure; wherein said first body section comprises: said peripheral side wall having an edge section adjacent to said edge, said edge section configured as a double wall structure; and a section of said peripheral side wall, adjacent to said edge section and between said edge section and said base wall, configured as a single wall structure.

2. The case of claim 1 wherein at least a majority, based on surface area, of the first body section is configured as a single wall structure.

3. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge wherein said first body section is a single molded piece and said second body section is another single molded piece; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of the first body section being configured as a double wall structure; a portion of the first body section being configured as a single wall structure; a portion of the second body section being configured as a double wall structure; and a portion of the second body section being configured as a single wall structure, wherein said first body section further comprises: said peripheral side wall configured as a single wall structure, said base wall configured as a double wall structure; a plurality of ribs disposed between said base section and said peripheral side wall, said ribs connecting said single wall structure to said double wall structure along a portion of said peripheral side wall that includes said opening.

4. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge wherein said first body section is a single molded piece and said second body section is another single molded piece; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of the first body section being configured as a double wall structure; a portion of the first body section being configured as a single wall structure; a portion of the second body section being configured as a double wall structure; and a portion of the second body section being configured as a single wall structure; at least one hinge member formed on said second body portion, each said hinge member disposed at a location where the at least one of the peripheral side walls is configured as a double wall structure, wherein walls of said double wall structure are bonded together at an area adjacent to the at least one hinge member.

5. The case of claim 4 further comprising: at least one latch member formed on one of said body portions; said at least one latch member at a location where the at least one of the peripheral side walls is configured as a double wall structure.

6. The case of claim 5 wherein walls of said double wall structure are bonded together at an area adjacent to the at least one latch member.

7. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge wherein said first body section is a single molded piece and said second body section is another single molded piece; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of the first body section being configured as a double wall structure; a portion of the first body section being configured as a single wall structure; a portion of the second body section being configured as a double wall structure; and a portion of the second body section being configured as a single wall structure; a handle connected to said second body section; an inner wall of said second body portion joined to an outer wall of said second body section to create a joint at said handle; said handle extending into said second body section and contacting said inner and outer wall at said joint.

8. The case of claim 1 wherein the single wall structures of the first and second body sections are formed by removal of a section of a wall of their respective single molded pieces.

9. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side wall defining an edge; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of each said first and second body sections being configured as a double wall structure; and a portion of at least one of said first and second body sections being configured as a single wall structure; wherein said first body section comprises: said peripheral side wall having an edge section adjacent to said edge, said edge section configures as a double wall structure; and a section of said peripheral side wall, adjacent to said edge section and between said edge section and said base wall, configured as a single wall structure.

10. The case of claim 9 wherein at least a majority, based on surface area, of the first body section is configured as a single wall structure.

11. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of each said first and second body sections being configured as a double wall structure; and a portion of at least one said first and second body sections being configured as a single wall structure, wherein said first body section further comprises: a plurality of ribs connecting portions of said double wall structure together.

12. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of each said first and second body sections being configured as a double wall structure; and a portion of at least one said first and second body sections being configured as a single wall structure; at least one hinge member formed on said second body section, said at least one hinge member disposed at a location where the at least one of the peripheral side walls is configured as a double wall structure; wherein walls of said double wall structure are bonded together at an area adjacent to the at least one hinge member.

13. The carrying case of claim 12 further comprising: at least one latch member formed on one of said body sections; said at least one latch member at a location where the at least one of the peripheral side walls is configured as a double wall structure.

14. The carrying case of claim 13 wherein walls of said double wall structure are bonded together at an area adjacent to the at least one latch member.

15. A hybrid double and single wall case comprising: a first body section and a second body section, each having a base wall and a peripheral side wall, said peripheral side walls each defining an edge; said first and second body sections pivotally connected with respect to each other and adapted to pivot between an open position and a closed position; a portion of each said first and second body sections being configured as a double wall structure; and a portion of at least one said first and second body sections being configured as a single wall structure; a handle connected to said second body section; an inner wall of said second body section joined to an outer wall of said second body section to create a joint at said handle; said handle extending into said second body section and contacting said inner and outer wall at said joint.

16. The carrying case of claim 9 wherein the single wall structure of said first and second sections is formed by removal of a section of a wall of the respective one of said first and second body sections.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a prior art double wall chainsaw case.

(2) FIG. 2 is a perspective view of another prior art double wall chainsaw case having a separate scabbard.

(3) FIG. 3 is perspective view of the chainsaw case in the open position.

(4) FIG. 4 is a perspective view of the chainsaw case of FIG. 3 in the closed position.

(5) FIG. 5 is a perspective view of the case of FIG. 3 showing cutout sections.

(6) FIG. 6 is a bottom view of the chainsaw case of FIG. 3 in the open position.

(7) FIG. 7 is a sectional view of the chainsaw case of FIG. 3 taken along line 7-7 in FIG. 6.

(8) FIG. 8 is another sectional view of the chainsaw case of FIG. 3 taken along line 8-8 in FIG. 6.

(9) FIGS. 9A and 9B are respectively bottom and interior perspective detail views of the case of FIG. 3.

(10) FIGS. 10A, 10B are respectively interior and exterior perspective detail views of the case of FIG. 3.

(11) FIG. 100 is a sectional detail view of the case of FIG. 3 taken along line 10c-10c of FIG. 10a.

(12) FIGS. 11A and 11B are respectively exterior and interior perspective detail views of the case of FIG. 3.

DETAILED DESCRIPTION OF THE INVENTION

(13) FIG. 3 shows a scabbard 10 with an end portion 100. The end portion is tapered to fit in an opening 200 of a bottom portion 20 of the chainsaw case. Protrusion 110 of the scabbard and recess 202 of the bottom portion interact to hold the end portion 100 in the opening 200. As shown, the opening and end portion are both tapered, which can both aid in manufacturing during the de-molding process and when placing the chainsaw having the scabbard applied thereto within the case. The tapered angle makes it easier to align the scabbard and opening. The taper can be an angle of 0-40 degrees and, preferably 1-30 degrees, more preferably 5-15 degrees and even more preferably approximately 10 degrees.

(14) The length of the scabbard may be smaller than the distance from the inner wall of the opening to the opposite wall, thereby allowing the end portion 100 of the scabbard to be disposed so that the scabbard extends into the case during shipment or display to take up less space. Since the scabbard is removable, different length scabbards can be provided, depending on the length of the bar of the chainsaw. Optionally, an adjustable or telescoping scabbard may be used to provide for different sized chainsaws.

(15) The bottom portion 20 contains a single wall section 210 (See FIG. 5) created by removal of cutout 211 located at the base of the bottom portion 20. A portion of the wall 212 of the bottom portion 20 located close to the opening 200 is a double wall construction. A section 240 of the bottom portion around the edge of the wall is configured as a double wall construction. Catches 230 and 232 are designed to interact with latches 330 and 332 to close the case. A double wall section similar to section 240 may be disposed around the edge of the top portion 30 as well. Hinges 250 and 256 connect the bottom 20 and top 30 portions. The top portion 30 has a double wall section 312 and single wall sections 310 and 320 (see FIG. 5) created by removal of cutouts 311 and 321. The single wall sections 310 and 320 may be located to receive sections of the chainsaw such as handles, guards or other that may extend from the body of the chainsaw. Thus, the configuration of sections 310 and 320 as single wall sections can save both space and material. A double wall section 340 is shown across the middle of the top portion 30, and this double wall section 340 is formed to receive a handle 350. The double wall section 340 provides added support to the handle section, because the weight of the chainsaw will be supported from the handle, and the location of double wall section 340 at the handle adds stiffness to the case where needed.

(16) The cutout sections 211, 311, 321 may be removed using an in-mold punching system, where the double wall structure is molded first and while the mold is closed, a portion of the mold moves to shear or cut off the respective cutout sections 211, 311, 321 along their respective edges. Therefore, when the double wall structure is initially molded without the cutout removals, the portions of the inner wall of the double wall sections where the cutout sections will be removed are designed to work with the in-mold punching system. Often, a side wall of the section to be removed is perpendicular to the plane of the punched hole of the cutout sections 211, 311, 321 to allow for the in-mold punching to function properly. The in-mold punching system saves time during the manufacturing process, thus further reducing the cost of the case.

(17) Based on surface area, the top portion 30 is configured with a ratio of single:double wall construction. This ratio may be 1:1 or preferably 2:1, more preferably 4:1 and even more preferably 8:1. Other ratios within the ranges of 1:1 to 8:1 are contemplated. The bottom portion 20 is also configured with a ratio of single:double wall construction. This ratio may also be 1:1 or preferably 2:1, more preferably 4:1 and even more preferably 8:1. Other ratios within these ranges are contemplated. The ratio may exceed 8:1, depending on the weight of the chainsaw and/or the level of protection required. The ratios may also be measured as beginning:remaining, where beginning represents the surface area before the punching of the double wall structure to create a single wall structure. Remaining represents the remaining surface area of the relevant wall. The ratios may be, for the inner wall of the lid or top portion 30, the beginning:remaining ratio may be in the range of 1:1-10:1 and preferrably 7.7:1. For the bottom portion 20, this beginning:remaining ratio may be in the range of 1:1-10:1 and preferably 3.4:1. The total inner surface beginning:remaining ratio may be in the range of 1:1-10:1 and preferably 4.6:1, and the total surface (inner and outer) beginning:remaining ratio may be in the range of 0.25:1-10:1 and preferably 1.63:1.

(18) FIG. 4 shows the chainsaw case in a closed position. Handle 350 is recessed into a section of the top portion 30 so that the handle may lay flat. Also, the double wall section 340 meets at the handle to provide extra support. The scabbard 10 is installed in the bottom section 20, and the top 30 and bottom 20 sections mate along an edge with the latches 332 and 330 interacting with catches 232 and 230 to hold the case in the closed position.

(19) FIG. 5 shows the cutout sections 211, 311 and 321 that are removed from the chainsaw case during manufacturing to provide the hybrid single and double wall construction. These cutout sections can be recycled into another blow molded case, thus saving material costs. The bottom portion 20 includes a base with raised sections 206 and a peripheral recess 208 that is configured to collect oil or grease from the chainsaw. Ribs 204 located near the opening 200 are formed by joining the outer wall and the inner wall near the opening to provide additional support at the opening 200. The raised sections 206 and peripheral recess 208 provide additional structure to the base of the wall that resists flexing and bending. For example, the raised sections 206 may form a corrugated type pattern that supports the weight of the chainsaw more effectively than a flat base wall without the raised sections.

(20) FIG. 6 shows the bottom of the chainsaw case in an open position. The peripheral recess 208 and the raised sections 206 are formed in the base of the bottom portion 20. The ribs 204 are formed by joining the outer wall and the inner wall of the bottom portion near the opening 200.

(21) FIG. 7 shows a cutaway of the bottom portion 20 along section line 7. Outer wall 22 and inner wall 24 form a double wall section near the opening 200. The ribs 204 join the outer and inner walls to provide extra support at the opening 200. The peripheral section of the inner wall 240 is positioned around the edge of the bottom section to provide additional support and to reduce the deformation of the case due to the weight of the chainsaw. Indent 252 and weld 254 support the case at the hinge where the top 30 and bottom 20 portions of the case are connected. Weld 254 may be configured to join or weld inner wall 240 and outer wall 242 near the edge of the bottom portion 20.

(22) FIG. 8 shows the top portion 30 having an inner 34 and outer 32 walls near the front of the case. Sections of the inner 34 wall are removed as previously discussed and shown. Double wall section 340 joins inner and outer walls at the handle 350 to provide additional support and rigidity to the chainsaw case. At the handle 350, two sections of the inner wall are each disposed at an angle, and meet at a flat section, where the flat section of the inner wall between the two angled walls joins to the outer wall for increased rigidity at the handle. The handle 350 may have an pin or pin section 352 that interacts with both the inner and outer walls, thus supporting the weight of the chainsaw. Double wall section 340 extends to the inner wall 34 of the top section 30, and therefore aids in transferring the weight from the handle to the inner wall 34 of the top section 30.

(23) FIGS. 9A and 9B show detail of the ribs 204. The ribs may be conically shaped within the outer wall 22 and these ribs 204 are joined to the inner wall 24 to provide added stiffness and strength to the wall of the bottom portion 20 near the opening 200. The conically shaped walls of the ribs 204 meet at a flat section, and this flat section is joined to the inner wall 24. Although the ribs have been shown on the bottom portion, the ribs could be created in the top section, for example, ribs could join the double wall portion 340 on either side of the handle to provide added stiffness. Further, the ribs may be created in the inner walls so that the conical shaped walls of the ribs are within the inner wall, so that the ribs extend from the inner wall and join to the outer wall.

(24) FIGS. 10A, 10B and 10C show detail views of catch 232 where indent 234 and weld 236 provide additional support to the catch 232. FIG. 10C shows a sectional view at the section line of 10A. Inner wall 240 and outer wall 242 create a double wall structure near the catch 232 to provide additional support to the case where the weight of the chainsaw will be concentrated. The weld 236 may join inner 240 and outer 242 walls for added strength. Optionally, the indent 234 and weld 236 may provide sufficient strength to not join the inner 240 and outer 242 walls as shown by FIG. 10C FIG. 11A shows the pin 256 of the hinge. FIG. 11B shows the indent 254 and weld 252 that provide additional support at the hinge. The indent and weld of the catch and the indent and weld of the hinge may have similar structures and may join or not join the inner or outer walls, depending on the required strength and stiffness for the case.

(25) The cases described herein can also stack upon each other in the open configuration. When a majority of the base of the bottom portion 20 is configured as a single wall structure, the stacking of the cases upon each other takes up less space in comparison to a double wall structure. This results in a larger number of cases fitting in standard shipping sizes or containers, which results in a savings on shipping costs. For example, the cases may stack so that 10% more cases fit inside a pallet sized box when compared to a traditional double wall case.