1. Field of the Invention
The invention presented herein is about a switching implement suitable for the remote-controlled switching of electrical components.
2. Related Art
The invention presented herein is about a switching implement suitable for the remote-controlled switching of electrical consumers. Standard vehicle configurations feature one or two fuse and relay boxes for frequently switching or small to medium loads. Many of these fuse and relay boxes are so-called smart junction boxes with an extra circuitry and sometimes included semiconductor switches.
A switching implement of this kind is described in EP 0 181 534 131 and other publications. This type of switching implement with its many relays and blow-out fuses for protection requires a fairly elaborate design and is of limited reliability due to its many fuses, relays and plug connections. It also leads to comparatively much power being lost during operation because every fuse, every relay coil, every relay contact, and every contact dissipates some of the power. Since the plug-in fuses need to be replaced every time a situation occurs that their job is to protect the vehicle against (e.g. overload or short circuit), the entire switching implement needs to be installed at a place in the vehicle where it can be accessed for maintenance.
The state of the art has revealed maintenance-free switching implements using semiconductor switches for actuating the electrical consumers, However, the highcurrent switching transistors deployed in these switching implements are very expensive. Thermal bimetal switching devices failed to become the standard means of overload and short-circuit protection because their design-specific disadvantages disallow their general use in motor vehicles.
EP 1 033 288 A1 describes a fusing system featuring a motor-driven actuator which can be remote controlled to reversibly break the contact of multiples lines. However, this fusing system allows but a single set sequence of on or off switching actions regarding the consumer lines. The fusing system with its single actuator fails to independently switch the different consumers on or off. Another fact is that having a motor break the contacts slows down the process of breaking the contacts whose long arc durations as specifically generated by short circuit currents will wear down the contacts faster, thereby shortening the life of the contacts.
Hence, the task of the current invention is to provide a switching implement for the remote-controlled switching of electrical components or groups of components, where the continuous power loss of the implement rates significantly lower than that of conventional fuse and relay boxes, where the design of the implement is of a small footprint, robust and cost-effective, and where the means of protection against overload and short circuit can be re-actuated which allows the switching implement to be installed in less accessible places in the vehicle.
The current invention accomplishes its objective by a switching implement of the aforementioned type.
The invention is about a switching implement for the remote-controlled switching of electrical consumers comprising:
The switching implement according to the invention is specifically designed for use in vehicles and is of a comparatively simple, robust and cost-efficient design compared with that of the fuse and relay boxes mentioned in the State of the Art section hereof. To turn off overloads and short circuits, the switching implement uses switches which can be reactivated and, thus, need not to be replaced after performing their protective action. Thus, the switching implement can be installed in relatively inaccessible places in the vehicle. Deployment of the switching implement as a replacement for a conventional fuse and relay box or as a module of an intelligent fuse and relay box can help reduce the space, material and mass of the module required to actuate the electrical consumers and to electrically protect the wiring connecting up the electrical consumers. The electromechanical, bistable switches may feature a moving switch contact holder holding at least one electrical switch contact and at least one immobile switch contact holder holding at least one switch contact. The moving switch contact holder could be a flexible switching contact spring, for example. Moving the bistable switch to the Closed position will make the switch contacts contact at a force allowing electric current to pass through the switch. Moving the switch to the Open position will force the switch contacts apart leaving a specified minimum contact clearance that will interrupt the flow of electric current. Designing the switches as bistable switches allows consumers or omnibus circuits, which normally remain connected to the onboard mains of the vehicle, to be selectively separated from the on-board mains in response to certain situations of the vehicle, e.g. parking for extended periods of time, loading the vehicle on-board a vessel, a nearly discharged battery, etc. Separation from the mains would require no separate bistable electrical relay or separate semiconductor switch for each of these consumers.
A specifically beneficial design variant suggests to design the at least one actuating element such that it can make two entirely independent movements that will allow to toggle each of the bistable switches to any of its logical states. The multiple bistable switches of the switching implement could be arranged in a line or in a circular arrangement. Or there is a possibility of arranging the bistable switches at several layers one on top of each other. The at least one actuating element of the switching implement is designed such that each of the bistable switches can be selectively actuated either in a movement of translation or a movement of rotation or a combined movement of translation and rotation.
Another design variant may extend the switching implement by an electronic control unit which is set to controlling the at least one actuating element with reference to external control signals. The electronic control unit could have at least one communication port connecting it with the on-board electrical system of the vehicle. If a request is received through the communication port to turn one of the bistable switches on or off, the actuating element can be moved to the relevant bistable switch. The bistable switch will be actuated and set to the requested switching state.
Another beneficial design variant suggests to set up the at least one actuating element for a non-contact switchover of the bistable switches.
The at least one actuating element may have at least one means of activation and at least one means of setting the position of the at least one means of activation.
The bistable switches may feature at least one means of operation by which the at least one means of activation of the actuating element can be manipulated. For example, the means of operation could have an operating section which makes up an integral unit with the moving switch contact holder of the bistable switch.
To allow for a non-contact activation of the bistable switches, the design may specify the at least one means of activation to be a solenoid. A solenoid will reliably ensure a non-contact switchover of the bistable switches of the switching implement if the means of operation of the switching bistable switches is set by means of magnetic force (for example from a ferromagnet or a permanent magnet).
To allow the reading in of the logical states of the bistable switches or the consumers connected to them during operation of the switching implement, a particularly beneficial design variant could include sensor elements in the switching implement where the sensor elements would be able to measure the temperature of the bistable switches and/or the current going through the bistable switches.
The sensor elements could be integrated in the bistable switches, for example. Deploying preferably electronic means of measuring the currents, short circuits and currents above admissible limits could be detected with reference to custom current vs. time characteristics and, once detected, could be interrupted by the actuating element. The turn-off characteristic of currents over time could thus be adapted to the admissible current vs. time characteristic of every consumer, wire or other component connected to the system at any point along the load line. Keeping track of load currents may allow the switching implement to also provide a master system for the vehicle's mains energy management with information about load currents and other details to support quiescent current management, energy consumption management and other energy management functions. This turns the switching implement into an intelligent, mechatronic feedback system.
To prevent the bistable switches or the electrical consumers connected to them from taking damage, a particularly beneficial design variant suggests protecting at least some of the bistable switches by means appropriately configured to turn off a bistable switch exposed to a temperature and/or a current in excess of the set maximum. Integrating a fuse function and a relay function into the bistable switches helps to reduce the efforts otherwise necessary to provide these functions as well as the efforts otherwise necessary to provide the appropriate electrical connections.
For example, the safety equipment may be made up of a bimetal actuator located inside the bistable switch or immediately attached to the bistable switch. A bimetal actuator can be fairly easily integrated in the bistable switch and would facilitate the reliable turn-off of the bistable switch in response to the temperature in the switch being above a set critical limit.
A particularly beneficial design variant suggests having the switching implement include means of reading the ambient temperature of the bistable switches and means of reading the mains voltage of the vehicle's on-board mains, and having these means be connected to the electronic control unit. This design would further improve the accuracy of electric current analyses. After measuring the ambient temperature of the bistable switches preferably using one or several temperature sensors and after measuring the on-board mains voltage, the readings are fed to the electronic control unit which will take care of their further processing.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The description of design variants below illustrates further features and benefits of the current invention with reference to the attached figures. The following is shown:
a is a lateral view of a first design variant of a bistable switch (open) for a switching implement.
b is a lateral view of the bistable switch shown in
c is a top view of the bistable switch shown in
a is a lateral view of a second design variant of a bistable switch (open) for a switching implement.
b is a lateral view of the bistable switch shown in
c is a top view of the bistable switch shown in
a is a lateral view of a third design variant of a bistable switch (open) for a switching implement.
b is a lateral view of the bistable switch shown in
c is a top view of the bistable switch shown in
a is a lateral view of a fourth design variant of a bistable switch (open) for a switching implement.
b is a lateral view of the bistable switch shown in
c is a top view of the bistable switch shown in
The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
In this design variant, the actuating element (3) consists of a means of activation (31) which, in this design variant, is a solenoid capable of activating the bistable switches (2). The actuating element (3) also contains a positioning device (30) for changing the position of the means of activation (31). In this design variant, the positioning device (30) consists of a drive for changing the position of the means of activation (31). The means of activation (31) is connected to the positioning device (30) which, in this design variant, is designed such that it will make the means of activation (31) perform a translational motion. The double arrow in
Using the positioning device (30) allows a selective motion of the means of activation (31) to any of the bistable switches (2). The means of activation (31) can then actuate the bistable switch (2) that was previously selected or that it was moved to and make the switch setting change from a first state to a second state or from the second state back to its first state. In this design variant, the setting of the bistable switches (2) is a non-contact operation performed by the means of activation (31) which, in this case, is a solenoid.
An alternative design not shown herein may include a means of activation (31) which operates such that one of its possible states is able to transport a mechanical effect from the positioning device (30) to one of the bistable switches and vice versa. In this alternative approach, the force required to change the setting of the bistable switch (2) would be exerted by the positioning device (30). To change the setting of the selected bistable switch (2), the means of activation (31) can be physically moved to that switch. There is also the possibility of the positioning device (30) moving the position of an actuator such that it can be operated by the means of activation (31) (possibly using another actuator) to actually operated the bistable switch (2).
Other alternative design variants of the switching implement (1) not shown herein either provide an option of the bistable switches (2) being arranged in two or more parallel or, if need be, opposing rows and the actuating element (3) and, specifically, the means of activation (31) being designed such that the different rows of bistable switches (2) can be selectively operated by means of the actuating element (3).
The design variants described herein can use a linear drive or a rotational drive plus plunger coil solenoid or plunger armature solenoid as the positioning device (30), where the drive is collocated with a linear shifter if the bistable switches (2) are in a linear arrangement. The linear shifter can be a belt and chain drive, a worm drive or similar mechanism. The drives for the switching implements (1) described herein can be servodrives or stepper motors.
To actuate the drives, either the control unit (4) previously described when discussing the first design variant of the switching implement (1) or a position encoder plus control circuitry can be used.
In the design variants of the switching implement (1) shown herein, an appropriate drive or a single-coil or multiple-coil solenoid (perhaps together with a permanent magnet), an electrothermal, piezo-electric or other electrically operated drive can be used as the means of activation (31). The means of operating the bistable switches (2) can be levers, articulated straight-line guides, snap springs, pinions or similar elements.
a to
The moving switch contact holder (20) has at least one electrical switch contact (21). At least one other electrical switch contact (23) is connected to the set switch contact holder (22). The switch contacts (21, 23) can be contact elements riveted or welded on or any other surfaces enabled to act as a switch contact. For example, specially coated surface areas of the switch contact holders (20, 22) can be used as switch contacts (21, 23).
The bistable switch (2) also has a housing (24). The figure illustrates that the bistable switch (2) has a holder (26) for the moving switch contact holder (20) some of which protrudes from the housing (24) as does some of the set switch contact holder (22). There is an option of letting the holder (26) be an integral part of the housing (24). When the switch is closed as shown in
The moving switch contact holder (20) and/or the spring elements acting upon this device include at least one means of operation which, when operated, will move the bistable switch (2) from one position to the other such that it could change states from ‘closed’ as shown in
The switching contact spring which, in this design variant, makes up the moving switch contact holder (20) features at least two resilient sections (201, 202) and marked by a bead (203) or a shortening of at least one of the resilient sections (201, 202) distorting it in forward, transverse or across the direction of spring action such that the switching contact spring (20) can at least partially evade distortion by moving to one of two possible stable positions.
The two switch contact holders (20, 22) or the holder (26) of the moving switch contact holder can be made of a single or multiple parts plus connectors (27, 28). To facilitate assembly, it is possible to make all or at least several of the contact elements from the same punching screen and to keep them separate during the process of assembly.
Apart from the connectors (27, 28) which are needed to carry the load current to the switch contact holders (20, 22), there can be additional connectors required for a low-interference electrical detection of the operating state of the bistable switch (2) (and specifically for measuring the load current).
At least some of the bistable switches (2) of the switching implement (1) can be protected by safety equipment enabled to automatically open a bistable switch (2) to interrupt the flow of electric current if an admissible temperature or an admissible maximum flow of electric current through the bistable switch (2) is exceeded.
a to
In the design variants of the bistable switch (2) described herein, the outgoing connectors (27, 28, 50, and 51) of the switch contact holders (20, 22) are blade connectors. Alternatively, they can be designed as soldered joints, press-fit connectors, plug-type sleeves or similar connectors of this kind. The connectors (27, 28, 50, 51) can point away from the housing (24) in any direction.
As various modifications could be made to the exemplary embodiments, as described above with reference to the corresponding illustrations, without departing from the scope of the invention, it is intended that all matter contained in the foregoing description and shown in the accompanying drawings shall be interpreted as illustrative rather than limiting. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims appended hereto and their equivalents.
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