WO2024037965A1 - Functional unit - Google Patents

Abstract

The invention relates to a functional unit (1) comprising a housing (2), wherein the housing (2) has a loading compartment (3) for at least one energy source (110), which is a gas cylinder, wherein the housing (2) has at least one functional compartment (4) for accommodating at least one functional device (40, 42, 44), wherein the functional unit (1) is designed as a self-contained unit, wherein a drawer (30) is located in the loading compartment (3), wherein an axis of rotation (31) is located in the loading compartment (3), wherein the drawer (30) can be rotated about the axis of rotation (31), wherein the drawer (30) has a floor surface (32), and wherein, when the drawer (30) is in a resting state, the bottom surface (32) is lower than a plane in which the axis of rotation (31) lies, wherein a rotational movement of the drawer (30) relative to the loading compartment (3) is blocked when in the resting state, wherein a connection (34) for a gas hose (35) is located in the vicinity of the axis of rotation (31).

Description

Functional unit

The present invention relates to a functional unit. It is used, for example, in a mobile home, a caravan or on another vehicle or e.g. B. on a boat.

Caravans or motorhomes are usually equipped with components such as heaters, air conditioners, refrigerators, hobs or hot water heaters. The energy required to operate these components is obtained, for example, from a car battery, solar cells or by burning diesel fuel or liquid gas. Particularly when using liquid gas, it is known that corresponding gas bottles are located in a so-called gas box, which is characterized primarily by the fact that it is open to the outside world in order to allow any escaping gas to escape. For operation, connections must then be laid between the individual components and the gas box. Standards and safety requirements must be met. This is therefore complex and cost-intensive.

The object on which the invention is based is to enable the attachment of components, e.g. B. in a caravan and to enable the required energy supply as easily as possible.

The invention solves the problem by a functional unit with a housing, the housing having a loading space for at least one energy source, which is a gas bottle, the housing having at least one functional space for accommodating at least one functional equipment, the functional unit being designed as a self-contained unit is, wherein a drawer is arranged in the loading space, wherein an axis of rotation is arranged in the loading space, the drawer being rotatable about the axis of rotation, the drawer having a floor surface, and wherein the floor surface is deeper than a level when the drawer is in a resting state , in which the axis of rotation lies, where in which In the idle state, a rotational movement of the drawer is blocked relative to the hold, with a connection for a gas hose being arranged near the axis of rotation.

The functional unit offers space for the gas bottle and at least one functional device, so that no separate connections, connections or fixing options need to be created. In particular, all connections between the energy source and the functional equipment or possibly several functional devices are located within the housing or are located directly on the housing. The functional unit is a self-contained, ready-to-install module that can be used, for example: B. can be mounted in a motorhome or caravan. The energy source is, for example, a gas bottle or an accumulator for electrical energy. The functional equipment is preferably a component permanently mounted in the functional unit. Alternatively, the functional equipment can be reversibly removed from the housing of the functional unit and z. B. can be replaced by a differently designed functional device. In one embodiment, several functional devices can be accommodated in the functional unit.

A functional device is therefore generally a device which converts a form of energy, which is preferably, but not only, provided by the energy source into another form of energy - in particular thermal energy. For example, if the energy source is a gas bottle and a functional device is a room air heater, the heater burns the gas that comes from the gas bottle. In an alternative embodiment, the functional equipment is an electrical heating element which receives electrical energy from an additional energy connection of the functional unit. Conversely, the energy source can be a battery or accumulator. In this case, the aforementioned electrical heating element would draw its energy from this battery. In other words: The functional unit accommodates a unit for providing energy - i.e. the energy source - and at least one energy consumer - i.e. the functional equipment. The functional unit is therefore a self-contained and ready-to-install module that includes functional equipment and its energy supply.

By arranging the axis of rotation in such a way that the drawer can be rotated about the axis of rotation and the floor surface when the drawer is at rest is lower than a plane in which the axis of rotation lies, the drawer automatically reaches its rest position when it has exceeded a dead center . In one embodiment, the energy source is located - directly or indirectly - on the floor surface of the drawer, which can be rotated about the axis of rotation of the loading space. In a resting state, i.e. in a state that is not rotated relative to the housing, the base surface is lower than the axis of rotation. This results in a kind of tilting out of the housing when the drawer is rotated around the axis of rotation. This makes it easier to remove and replace the power source. This is particularly advantageous with a usually heavy gas bottle as an energy source.

In the idle state, rotation of the drawer relative to the hold is blocked. In this embodiment, a barrier is provided to prevent the drawer from being moved unintentionally. In one embodiment, this lock is effected by a door that is located in front of the cargo space.

By arranging the connection for a gas hose near the axis of rotation, a gas hose that is connected to the connection as part of the functional unit and to the gas bottle experiences only little mechanical stress and preferably only a small change in length. The proximity of the rotation axis and connection ensures that the gas hose can only carry out a specific and well-defined movement. This also prevents the gas hose from being installed incorrectly, which could potentially cause the hose to get pinched. The defined movement also prevents unacceptably small bending radii, which could damage the hose.

One embodiment provides that the loading space and the functional space are decoupled from each other with regard to the exchange of air. In this Design prevents air from getting into the functional space from the cargo space. This is relevant, for example, if the energy source is a gas bottle. In this case, no gas can enter the functional space uncontrolled.

In a further embodiment, the loading space is completely decoupled from the remaining volume of the housing with regard to the exchange of air.

In one embodiment, the cargo space has a separate air opening. In this configuration, for example, gas can escape from the cargo space. The air opening preferably has no further contact with the rest of the interior of the housing. There is therefore preferably no air or gas transfer between the air opening and a functional space.

One embodiment is that the functional equipment is an air temperature control device, that the air temperature control device has at least one air outlet, and that the air outlet opens outside the housing. In this embodiment, the functional equipment allows air to be cooled or heated. It is therefore, for example, an air conditioning unit or an air heater, which z. B. obtains a combustible gas from a gas bottle as an energy source. The tempered air is led out of the housing via an air outlet.

In one embodiment, the air temperature control device allows, in addition to heating the air, also the heating of a liquid, e.g. B. Process water.

In one embodiment, the functional equipment is a - preferably electrical - heating element, the heating element having a decoupling unit for thermal energy, and the decoupling unit opening into an interior of the housing. In this embodiment, heat generated by the functional equipment, i.e. the thermal energy, enters the housing. In one embodiment, the decoupling unit is implemented by a thermally conductive component. In an alternative embodiment, it is the decoupling unit for example, a recess in a wall component or, for example, an adjustable air flap.

In one embodiment, the decoupling unit is connected to another functional space. In this embodiment there are at least two functional spaces. The thermal energy can be transferred from functional equipment in one of the functional spaces to the other functional space.

In one embodiment it is provided that the thermal energy, which is generated by functional equipment in a first functional space, is conducted into a second functional space. Preferably, additional thermal energy, which is generated by further functional equipment in the second functional space, is transferred to the first functional space. In one embodiment, this exchange is realized by air circulating between the two functional spaces. Thus, for example, the decoupling unit is a closable air flap.

In one embodiment, it is an electrical heating element in which electrical current is converted into heat via the electrical resistance.

In an alternative embodiment, the functional equipment is an air conditioning device that cools the interior of the functional unit.

In one embodiment, the thermal energy of the heating element in particular is used to control the temperature of the energy source. For example, a combustible gas present in liquefied form in the energy source is converted from the liquid to the gaseous state. Alternatively, an electrical energy source such as an accumulator or a battery is cooled.

In one embodiment, the air outlet opens outside the housing and has a grille. In a further embodiment, the air outlet has at least one connection option for connecting an air pipe or air hose.

According to one embodiment, the functional device is a liquid heater. This is, for example, a boiler or a thermal bath as variants of a water heater.

Alternatively or additionally, the functional equipment is a hob.

One embodiment provides that the functional unit also has an interface for connection to an additional energy source located outside the functional unit. In this embodiment, the functional unit allows the connection of another energy source, e.g. B. can be connected to the functional equipment of the functional unit and then supplies it with energy. Alternatively or additionally, in one embodiment it is provided that the energy source in the functional unit is supplied with energy, i.e. refilled, by the additional energy source. In one embodiment, the additional energy source is a gas bottle. Alternatively, it is an electrical voltage source.

One embodiment includes that the interface has an adapting device, and that the adapting device adapts a form of energy provided by the additional energy source to operating parameters specified for the functional unit. If the energy source and the additional energy source are, for example, gas bottles, the adjusting device has a regulator that regulates the pressure of the additional energy source to a necessary standard pressure for the functional equipment. Depending on the design, the adapting device is completely or partially integrated into the interface. In one embodiment, components of the adapting device can be arranged away from the interface. However, the assignment still exists from the adapting device to the interface. One embodiment provides that the functional unit further has a control unit, and that the control unit is coupled at least to the functional equipment in order to intervene on the functional equipment. In this embodiment, a control unit is present which intervenes on the functional equipment and controls or regulates it. In one embodiment, the control unit distributes thermal energy that comes from a functional device to at least one further functional device and/or to the interior space in the housing and/or to the exterior space around the functional unit. For example, a room air heater can be used to enable a thermal water heater to provide hot water more quickly.

In a further embodiment, the functional unit has at least one sensor, with the control unit receiving and processing measurement signals from the sensor. In this embodiment, for example, the internal temperature in the housing is regulated by the control unit operating a heater based on temperature measurements. If the form of energy in the energy source is, for example, a gas that only changes to the gaseous state above a certain temperature, the control unit regulates z. B. an electric heating element until this temperature is reached. Then gas operation takes place. The functional unit therefore preferably also has a second energy source, e.g. B. via a connection to an electrical energy network. In an alternative embodiment, the control unit ensures that the temperature in the functional unit does not become too high. If such a case occurs, the control unit then switches off at least one functional device, for example.

The following embodiments relate to the area in which the energy source is installed.

One embodiment is that a thermally conductive unit is arranged in the cargo space. The thermally conductive unit is preferably coupled to the energy source, so that thermal energy can be supplied to or removed from the energy source. If the energy source is, for example, a gas bottle with a liquefied combustible gas, so it can be heated via the thermally conductive unit. Alternatively, if the energy source is a storage device for electrical energy, cooling can be carried out via the thermally conductive unit.

One embodiment provides that the thermally conductive unit is coupled to a decoupling unit of the functional equipment. In this embodiment, the functional unit has functional equipment that can ensure heating or cooling in it. A thermally conductive connection is created from the functional equipment to the thermally conductive unit and then preferably to the energy source via the decoupling unit. If the functional equipment is, for example, an electrical heating element, it outputs thermal energy via the decoupling unit, which heats the energy source via the thermally conductive unit.

In one embodiment, a movable door is arranged in front of the loading space.

The door (as a general name for a unit that reversibly closes a room on one side) is, in one embodiment, part of a holding device for holding the energy source, for example a gas bottle, in a locked position of use. The door therefore preferably prevents the drawer from tipping over. The user thus completes a lock by tilting the drawer into the rest position and bringing the door into the closed position. This simplifies the application, since e.g. B. no tension bands or straps need to be guided around the gas bottle and tightened.

One embodiment provides that the functional unit can be subjected to a standard test, and that after it has been subjected to a standard test and is thereby approved in the assembled state of the functional unit at an installation location, the approval continues to apply. In this embodiment, the functional unit is subjected to a test to determine whether the standards required for the application are met. The functional unit is then z. B. mounted in a motorhome. The functional unit is so self-contained that assembly meets the approval conditions nothing changes. The functional unit can therefore be manufactured in such a way that it only needs to be set up and fixed by a mobile home manufacturer. All relevant normative or general legal requirements have already been met and no inspection needs to be carried out in the assembled state. Such a test is e.g. B. gas testing when liquid gas is used as an energy source. A gas test refers to the tightness of the entire system, which consists, for example, of devices, connection fittings, lines, regulators or shut-off devices. This overall system is preferably completely encompassed by the functional unit and is subjected to a test before assembly in the application area.

According to one embodiment, the functional unit has several functional devices. The functional equipment is partly the same or all designed differently. In one version, for example, the functional unit has an electric heating element, an air heating device and a water heater.

According to one embodiment of the invention, it is provided that the drawer interacts with the housing in such a way that the drawer is automatically locked in a direction parallel to the pivot axis when the drawer is in the idle state. A user does not have to take any additional steps to lock the drawer when it is correctly inserted into the housing. Aside from an increase in convenience, this also means that a user cannot forget and it is not possible to drive with a charger that is not properly secured.

The automatic locking can be achieved by positive locking designs provided on the housing and the drawer, which automatically engage each other when the drawer is lowered to the rest position. The form-fitting designs can be projections and corresponding recesses that mesh with one another. In particular, the base surface can form a positive fit with the housing in the resting state. In one embodiment, the base surface rests on a component inside the housing.

The drawer preferably has an actuating element with which the gas bottle can be closed and opened from the outside, i.e. its shut-off valve can be actuated. The actuating element can have color coding so that a user can see at a glance whether the shut-off valve is open or closed.

In detail, there are a variety of options for designing and developing the functional unit according to the invention. Reference is made to the following description of exemplary embodiments in conjunction with the drawing. Show it:

1: a schematic representation of a functional unit according to the invention in a state mounted in a mobile home,

Fig. 2: a partially sectioned spatial representation of a functional unit and

Fig. 3: a section through a part of the functional unit of Fig. 2 in two different states (a) closed, b) opened).

Fig. 1 shows schematically a functional unit 1 within a room 100, as is the case, for example, within a mobile home or a caravan.

An important aspect is that a connection - indicated by the dashed line - between the energy source 110 and the functional equipment 40, 42, 44 only exists within the housing 2 of the functional unit 1. There is therefore no effort for relocating components outside the functional unit 1. The connections may also include all components, such as. B. include shut-off valves or regulators etc., which are required in each case. In the example shown, the functional unit 1 has three functional devices 40, 42, 44. In this example, these are a water heater 40 (also called a liquid heater), a room air heater 42 (also called an air temperature control device) and an electric heater 44 (also called a heater). called an electrical heating element), which serves to heat the energy source 110. For this purpose, the electric heating device 44 is also located nearby below the energy source 110. Accordingly, the room air heater 42 has an air outlet 43 which opens outside the housing 2. The electrical heating device 44 has an air outlet 45 which opens inside the housing 2.

A loading space 3 is assigned to the energy source 110. A special design of the loading space 3 will be described in connection with FIG. 3. A functional space 4 is each assigned to the three functional devices 40, 42, 44. The functional spaces 4 are indicated here separately from one another, but in an alternative embodiment (not shown) they can also merge into one another or partially overlap one another.

A control unit 6 is also arranged in the functional unit 2, which is connected to a sensor 7 and receives measurement data from it. The control unit 6 is connected to a user's input unit, for example via a Bluetooth connection, so that the user can specify target values. The control unit 6 acts on the functional devices 40, 42, 44 (only one connection is indicated here). Furthermore, the control unit 6 is also connected here to the energy source 110 and more precisely to a fill level sensor - not shown here - which, in the exemplary embodiment shown, determines the fill level of a liquid gas within the energy source 110. In one variant, the control unit 6 regulates how much heat is conducted from the functional devices 40, 42, 44 into the housing 2 and how much is conducted to the outside.

The functional unit 2 has an interface 5 to which an external additional energy source 111 outside the functional unit 2 and here outside of the enclosed space 100 is connected. The interface 5 has an adaptation device 50, which adapts the energy provided by the additional energy source 111 to the requirements in the functional unit 1. In the example shown, the energy source 110 is a liquid gas bottle. Accordingly, the additional energy source 111 should also be a gas bottle. Thus, the adjustment device 50 has a pressure regulator here, which regulates the gas pressure provided by the additional energy source 11 to a predetermined target pressure.

2 allows a look at an embodiment of the functional unit 1.

At the top of the housing 2 is the loading space 3 for the energy source 110, which is a gas bottle. The interface 5 is located on the back of the housing 2.

In the embodiment shown, there is an air outlet 43 near the floor, which is designed here as an air grille and through which heated room air is blown out. Above this there is a decoupling unit 45, via which thermal energy is removed from the electrical heating device in order to be available in the housing 2.

The loading space 3 is decoupled from the rest of the interior of the housing 2 with regard to the exchange of air. This is relevant because the energy source 110 is a gas bottle. Since no air exchange takes place, no gas can get from the loading space 3 into the remaining space of the housing 2. In other words, the decoupling in relation to the exchange of air can also be described as the gas-tightness of the cargo space 3.

It is indicated that an exhaust pipe is located on the back of the housing 2. The relevant components are therefore not only attached in the housing 2, but also if necessary. Below the loading space 3, two functional spaces 4 can be seen, in each of which functional equipment 40, 42 is arranged. An exchange of air is possible between the functional rooms 4, through which the exchange of thermal energy is realized here. This is indicated here by the recess, which can be closed reversibly and/or gradually with a flap (not shown here). This, especially in conjunction with the air outlet 43, allows the extraction or circulation of thermal energy to be controlled.

Furthermore, the cargo space 3 receives thermal energy from a heating or heating unit - not shown here - which is located below the cargo space 3. This is, for example, an electrical heating element which is supplied with electrical energy from outside the functional unit. The electrical heating element here allows in particular the heating of the energy source 110, so that the other functional equipment can then be supplied with the gas converted into the gaseous state. The electrical heating element may be the electrical heating device 44 described above.

Fig. 3 is dedicated to the loading space 3 for the energy source 110 - which is gas-tight with respect to the rest of the interior of the housing. Fig. 3 a) shows a rest state and Fig. 3 b) shows a tilted state.

Inside the housing 2 is the loading space 3, which is closed at the front by a movable and lockable door (alternative name: flap) 33. In the loading space 3 there is a drawer 30 which can be rotated about an axis of rotation 31. This axis of rotation 31 is realized, for example, by a rod fastened in the housing 2. The drawer 30 and thus the energy source 110 can thus be tilted out of the housing 2. Near the axis of rotation 31, which here is perpendicular to the plane of the drawing, there is a connection 34, onto which a gas hose 35 opens, which is connected to the energy source 110. By placing it near the axis of rotation 31, the gas hose experiences little mechanical stress and it is also ensures safe laying of the hose within the cargo space 3.

Within the drawer 30, the energy source 110 stands - indirectly via a thermally conductive unit 36 - on a floor surface 32 (see FIG. 3 b)), which in turn rests on a level of the housing 2 in the idle state (see FIG. 3 a)). . In the resting state, the bottom surface 32 is located below the plane in which the axis of rotation 31 lies, which results in the forward tilting movement in the rotated state. As can be seen in FIG. 3 b), the drawer 30 is shaped in such a way that it can be tilted out of the housing 2. In an alternative embodiment - not shown - the energy source 110 is located above the floor surface 32 by a holding mechanism that is coupled, for example, to the drawer 30, so that a gap is created. In a further alternative - and not shown - embodiment, the bottom surface 32 does not come to rest on a level or support of the housing 2, but is in a position that does not allow further tilting into the housing 2.

Positive locking designs 38 are provided here on the housing 2, which in the specific exemplary embodiment are designed as at least one projection. Complementary form-fitting designs 39 are provided on the drawer 30, which in the specific exemplary embodiment are designed as a recess. When the drawer is lowered from its position shown in Figure 3b into the rest position of Figure 3a, the form-fitting designs 38, 39 automatically engage one another, so that the drawer 30 is secured against displacement parallel to the pivot axis. Assuming that the door 33 is locked and therefore the drawer 30 remains in its rest position, the gas bottle contained therein is reliably secured against displacement in any direction.

The drawer 30 preferably has an actuating element (not shown in the figures) with which the gas bottle can be closed and opened from the outside, i.e. its shut-off valve can be actuated. It is therefore not necessary for the operator to have access to the internal shut-off valve has. The actuating element can be a rotary wheel or something similar.

Between the bottom surface 32 and the bottom of the energy source 110 there is also a thermally conductive base plate as an example of the thermally conductive unit 36, which is coupled to the decoupling unit 45 of the electrical heating element 44 (see FIG. 1). The energy source 110 can thus be heated.

In the embodiment shown, the loading space 3 has its own air opening 37. This air opening 37 is designed here so that it is long enough to pass through a wall, for example. B. a mobile home to pass through. The air opening 37 thus allows, for example, that escaping gas can be discharged directly into the environment. In the embodiment shown, the air opening 37 and the interface 5 are designed as a common component. In an alternative embodiment - not shown - the air opening 37 is designed separately or is only the air opening 37 and no interface 5 is present.

Claims

Claims Functional unit (1) with a housing (2), the housing (2) having a loading space (3) for at least one energy source (110), which is a gas bottle, the housing (2) having at least one functional space (4). Accommodating at least one functional device (40, 42, 44), the functional unit (1) being designed as a self-contained unit, a drawer (30) being arranged in the loading space (3), wherein in the loading space (3) a The axis of rotation (31) is arranged, the drawer (30) being rotatable about the axis of rotation (31), the drawer (30) having a bottom surface (32), and the base surface (32) being in a resting state of the drawer (30). is deeper than a plane in which the axis of rotation (31) lies, wherein in the idle state a rotational movement of the drawer (30) is blocked relative to the hold (3), with a connection (34) for a gas hose (35) nearby the axis of rotation (31) is arranged. Functional unit (1) according to claim 1, wherein the loading space (3) and the functional space (4) are decoupled from one another with regard to the exchange of air. Functional unit (1) according to claim 1 or 2, wherein the functional equipment (42) is an air temperature control device, the air temperature control device (42) having at least one air outlet (43), and the air outlet (43) outside the housing (2 ) ends. Functional unit (1) according to claim 3, wherein the air outlet (43) has a grille. Functional unit (1) according to one of claims 1 to 4, wherein the functional equipment (44) is a - preferably electrical - heating element, wherein the heating element (44) has a decoupling unit (45) for thermal energy, and wherein the decoupling unit (45) opens into an interior of the housing (2). Functional unit (1) according to one of claims 1 to 5, wherein the functional equipment (40) is a liquid heater, or wherein the functional equipment (40) is a hob. Functional unit (1) according to one of claims 1 to 6, wherein the functional unit (1) further has an interface (5) for connection to an additional energy source (111) located outside the functional unit (1). Functional unit (1) according to claim 7, wherein the interface (5) has an adapting device (50), and wherein the adapting device (50) provides a form of energy, which is provided by the additional energy source (111), for the functional unit (1). adjusts specified operating parameters. Functional unit (1) according to one of claims 1 to 8, wherein the functional unit (1) further comprises a control unit (6), and wherein the control unit (6) is coupled at least to the functional equipment (40) in order to access the functional equipment (40). to intervene. Functional unit (1) according to claim 9, wherein the functional unit (1) has at least one sensor (7), and wherein the control unit (6) receives and processes measurement signals from the sensor (7). 11. Functional unit (1) according to one of claims 1 to 10, wherein a thermally conductive unit (36) is arranged in the loading space (3). 12. Functional unit (1) according to claim 11, wherein the thermally conductive unit (36) is coupled to a decoupling unit (45) of the functional equipment (44). 13. Functional unit (1) according to one of claims 1 to 12, wherein a movable door (33) is arranged in front of the loading space (3). 14. Functional unit (1) according to one of claims 1 to 13, wherein the functional unit (1) can be subjected to a standard test, and after subjecting it to a standard test and thereby obtaining approval in the assembled state of the functional unit (1) at an installation location (100), the approval continues to exist. 15. Functional unit (1) according to one of claims 1 to 14, wherein the functional unit (1) has a plurality of functional devices (40, 42, 44). 16. Functional unit (1) according to one of the preceding claims, wherein the drawer (30) interacts with the housing (2) in such a way that the drawer (30) is automatically locked in a direction parallel to the pivot axis when the drawer (30) is is in idle state. 17. Functional unit (1) according to claim 16, wherein positive locking designs (38, 39) are provided on the housing (2) and on the drawer (30), which automatically engage with one another when the drawer (30) is lowered into the idle state. Functional unit (1) according to one of the preceding claims, wherein the drawer (30) has an actuating element with which the gas bottle can be closed and opened from the outside.