Lunchbox

Abstract

The invention relates to a lunchbox for storing, transporting and heating food, in particular food prepared for consumption. This should be easy to handle. The lunchbox comprises an upper shell (1) and a lower shell (2) which connected to one another in a hinged manner on one longitudinal side, wherein a closure is provided on the opposite longitudinal side. A shell having a circumferential and L-shaped angled edge region is arranged in the lower shell (2), which is assigned a thermal insulation and a heating element, wherein a groove for receiving a seal is formed in the circumferential edge region of the shell.

Claims

1. A lunchbox for storing, for transporting and for heating food, in particular food prepared for consumption, comprising; an upper shell and a lower shell, which are connected to one another in a hinged manner on one longitudinal side, wherein a closure is provided on the opposite longitudinal side; a shell having a circumferential and angled edge region being arranged in the lower shell, which comprises a thermal insulation and a film-type electrical heating element; a groove for receiving a seal being formed in the circumferential edge region of the shell; and a power connection socket provided on the upper shell and/or the lower shell, wherein the thermal insulation and the heating element extend at least over the base of the shell and at least partially enclose the side walls of the shell.

2. The lunchbox according to claim 1, wherein a pressure equalizing element is attached in the upper shell.

3. The lunchbox according to claim 1, wherein the upper shell also comprises a thermal insulation and an electrical heating element.

4. The lunchbox according to claim 1, wherein the circumferential edge of the shell is located in the region of a dividing plane between the upper shell and the lower shell.

5. The lunchbox according to claim 4, wherein the upper shell and the lower shell abut against one another flat and in an overlapping manner in the dividing plane.

6. The lunchbox according to claim 1, wherein the circumferential edge regions of the upper shell and the lower shell are configured to be corresponding in shape and fulfilling a sealing function.

7. The lunchbox according to claim 1, wherein the shell has an L-shaped edge region.

8. The lunchbox according to claim 1, wherein the electrical heating element comprises a heating film.

9. The lunchbox according to claim 1, further comprising an electronic control unit.

10. The lunchbox according to claim 9, wherein the electronic control unit is disposed on the lower shell and connected to the power connection socket.

11. The lunchbox according to claim 9, wherein the electronic control unit is configured to allow different heating modes in the lunchbox.

12. A lunchbox for storing, for transporting and for heating food, comprising: an upper shell; a lower shell connected to the upper shell in a hinged manner on one longitudinal side, wherein a closure is provided on an opposite longitudinal side; a shell arranged in the lower shell to receive heatable foods, the shell having a circumferential and angled edge region, the shell comprising: a thermal insulation; a film-type electrical heating element; and a groove formed in the circumferential and angled edge region of the shell; a seal configured to be received in the groove; and a power connection socket provided on the upper shell or the lower shell.

13. A lunchbox for storing, for transporting and for heating food, in particular food prepared for consumption, comprising; an upper shell and a lower shell, which are connected to one another in a hinged manner on one longitudinal side, wherein a closure is provided on the opposite longitudinal side; a shell having a circumferential and angled edge region being arranged in the lower shell, which comprises a thermal insulation and a film-type electrical heating element; and a groove for receiving a seal being formed in the circumferential edge region of the shell; and wherein the thermal insulation and the heating element extend at least over the base of the shell and at least partially enclose the side walls of the shell.

14. A lunchbox for storing, for transporting and for heating food, in particular food prepared for consumption, comprising; an upper shell and a lower shell, which are connected to one another in a hinged manner on one longitudinal side, wherein a closure is provided on the opposite longitudinal side; a shell having a circumferential and angled edge region being arranged in the lower shell, which comprises a thermal insulation and a film-type electrical heating element; a groove for receiving a seal being formed in the circumferential edge region of the shell; a power connection socket provided on the upper shell and/or the lower shell; and an electronic control unit, wherein the thermal insulation and the heating element extend at least over the base of the shell and at least partially enclose the side walls of the shell.

Description

(1) The invention will be described in detail hereinafter in an exemplary embodiment with reference to the drawings. In the drawings

(2) FIG. 1: shows a lunchbox according to the invention;

(3) FIG. 2: shows the lunchbox according to FIG. 1 in a different view;

(4) FIG. 3: shows the lunchbox according to FIG. 1, opened;

(5) FIG. 4: shows the lunchbox according to FIG. 1 in section;

(6) FIG. 5: shows the lunchbox according to FIG. 4, opened,

(7) FIG. 6: shows details of the lunchbox according to FIG. 4.

(8) A lunchbox 30 according to the invention (FIGS. 1, 2) comprises an upper shell 1 and a lower shell 2, in each case made of plastic and/or metal, for example, polypropylene (PP), wherein the upper shell 1 functions as a lid and is substantially flatter compared to the lower shell 2. The upper shell 1 and the lower shell 2 are connected to one another in a hinged manner on one longitudinal side by means of a moulded-on film hinge 3, wherein instead of the film hinge 3 a pivot hinge which is fastened to the upper and lower shell, or similar, is also possible.

(9) By means of a pivot hinge the upper shell 1 could be opened up with respect to the film hinge and it would also be easier to replace than in the case of a film hinge.

(10) A snap-in closure 4 (or snap closure) is provided on the side opposite the film hinge 3.

(11) Upper shell 1 and lower shell 2 lie flat in the dividing plane 22 and abut against one another in an overlapping manner with an overhang 21 of the upper shell 1.

(12) In the example, the height of the lower shell 2 is a multiple of the height of the upper shell 1, at least one and a half times.

(13) A power connection socket 5 is provided on a longitudinal wall of the lower shell 2, wherein this can be configured in the form of a usual plug and also as a USB connection. Alternatively or additionally, such a power connection socket 5 can also be provided in the upper shell 1.

(14) Furthermore, an LED 6 as a status display (heating) and start button is disposed on the longitudinal wall of the lower shell 2. A pressure compensating element 7, not described in detail, is provided in the upper shell 1.

(15) The circumferential edge regions 8 (FIG. 3) of upper shell 1 and lower shell 2 are configured to correspond in shape so that they can function as a seal or can receive a sealing element 9. This sealing element is inserted in a near-edge groove 10 of the lower shell 2.

(16) A shell 11 for holding the food to be heated is also part of the lunchbox 30.

(17) The shell 11 is formed for example of an aluminium material having a thickness of 0.5 mm and disposed in the lower shell 2. The shell 11 has a circumferentially moulded-on edge region which is angled in an L shape.

(18) The shell 11 is suspended in the groove 10 of the lower shell 2 by means of the smaller leg 24 of the edge region. A groove 23 in which a seal 12, for example, an O ring, is inserted, is likewise formed in the longer horizontal leg of the circumferential edge region. During closure of the upper shell 1 a double web 13 presses gently onto the seal 12 (FIG. 4), fixes this and the edge region of the shell 11 so that a tight closure of the lunchbox 30 is achieved in the dividing plane 22.

(19) The shell 11 can additionally be fixed in position in the lower shell 2 by means of snap-in lugs 16, 18 and/or click connections. For this purpose the lower shell has at least two spaced-apart shafts 19 near the wall which are provided with a snap-in lug 18 at the upper end (FIGS. 4, 5).

(20) However, a snap-in element with a snap-in lug could also be placed on the shafts 19, wherein in this embodiment the shafts 19 would be configured without snap-in lugs 18.

(21) These snap-in lugs 18 of the snap-in element press against the snap-in lugs 16 formed on the shell 11 so that the shell 11 is fixed in its position.

(22) The shell 11 can easily be removed from the lower shell 2 for cleaning or other purposes.

(23) Instead of this type of fastening, an arrangement of the shell 11 by means of an adhesive connection or similar would also be possible. In this case, the sealing element 9 could be omitted.

(24) The shell 11 and the lower shell 2 are adapted to one another or matched to one another in their design and shaping, for example by means of the snap-in lugs 16 and corresponding-shape mating elements of the shell 11.

(25) Thus, shells 11 which are differently shaped in detail can be used or inserted into the lower shell 2.

(26) For example, dimples 25, a snap-in element or a guide rail can be provided in the base region of the lower shell 2 in order to pre-define the shell shape used. By means of a precisely fitting shape on these dimples, the shell 11 is held in its position and also cannot be inserted upside down (safety feature). The dimples 25 at the same time serve for easy exchange of the shell 11 in order to ensure that the shell 11 is always inserted correctly.

(27) As a further safety element, tensioned positioning grids 20, positioning gussets or the like which hold the shell 11 in its position can also be provided in the edge region of the lower shell 2. They afford the possibility of possibly also providing another guide rail in the side region of the lower shell 2.

(28) Provided between the inner wall of the lower shell 2 and the shell 11 is a thermal insulation, for example made of a PUR integral foam, wherein another heating element 15 with a heating film is attached between this and the shell 11. The thermal insulation 14 could however also be formed from a Keraguss S moulding, an aerogel moulding or an EPS moulding.

(29) Thermal insulation 14 and heating film 15 can cover the base region of the shell 11 (FIG. 5) or also preferably also surround or enclose the side walls of the shell 11 at least as far as the snap-in lugs 16 (FIG. 4).

(30) In addition, the inner side of the upper shell 1 can also be provided with such a thermal insulation 14 and a heating element 15.

(31) A connection between the power connection socket 5 and a control electronic unit 17 as well as to the heating element 15 is made by means of cable connections not shown.

(32) The control electronic unit 17 is located on a flat board which in turn is placed in a space-saving manner on the inner wall of the lower shell 2 (FIG. 5). The control electronic unit 17 contains the electronic control, a safety circuit, a load switch and also a power pack. The electronic control should comprise at least a temperature sensor, a heating switch, the start-stop switch and the output for the LED 6. The electronic control can also allow different heating modes, for example lower and/or upper heat.

(33) The heating element 15 consists in a manner known per se of a metallic heating film which is embedded between two silicone layers for electrical insulation. However, for example, Kapton heating films, polyester heating films or contact heating elements can be used. The power supply can comprise 5 V to 240 V, including the usual tolerances. For example, at 5 V or 12 V DC no special safety measures need to be provided. In an embodiment using 230 V DC, the shell 11 must either be earthed or the aforesaid double electrical insulation must be attached. When selecting the connection variants, the current rating, temperature and resistance to cleaning agents must be taken into account. The electrical connections are watertight.

(34) The heating power of the heating film 15 should be at least about 20-150 W in order to enable heating of the food if necessary up to about 140 C. Depending on the food, lower or higher heating powers can be permissible wherein the values also depend on whether a heating element is only provided in the lower shell 2 or is also provided in the upper shell 1. When a heating element is arranged in the upper shell 1, its heating power is normally less than in the lower shell 2. The lunchbox is connected to the power source to heat the food and the start button which actuates the LED 6. By lighting up the LED 6 signals the heating process over a time duration pre-set in the control electronics 17. After the heating time has elapsed, the control electronic unit switches off the heating film and the LED 6 goes out. Other operating modes can be programmed.

REFERENCE LIST

(35) 1 Upper shell 2 Lower shell 3 Film hinge 4 Snap-in closure 5 Power connection socket 6 LED 7 Pressure compensating element 8 Edge region 9 Sealing element 10 Groove 11 Shell 12 Seal 13 Double web 14 Insulation 15 Heating element 16 Snap-in lugs 17 Control electronic unit 18 Snap-in lugs 19 Shaft 20 Positioning grid 21 Overhang 22 Dividing plane 23 Groove 24 Leg 25 Dimple 30 Lunchbox