DE102021126339A1 - Battery and method for securing a battery pole of a battery - Google Patents

Abstract

A battery (106) is described, which comprises a housing (200) and battery poles (201, 202) arranged on the housing (200), of which at least one contactable battery pole (202) is formed, with a battery-external contact element ( 212) to be connected. The battery (106) also includes one or more battery cells (205) arranged in the housing (200) and designed to cause a voltage at the battery poles (201, 202) when the one or more battery cells (205) are galvanically conductive are connected to the battery poles (201, 202). The battery (106) is designed in such a way that the contactable battery pole (202) is only electrically conductively connected to the one or more battery cells (205) when the battery-external contact element (212) is connected to the contactable battery pole (202).

Description

The invention relates to a battery and a method for protecting a battery pole of a battery.

A vehicle typically has at least one battery for storing electrical energy. The battery can be a lead battery or a lithium-ion battery, for example. The battery can be designed to supply electrical consumers in a low-voltage (NV) vehicle electrical system with electrical energy, e.g. with a nominal voltage of 12V or 48V.

The battery typically has two battery poles, a plus pole and a minus pole, which are connected to corresponding contact elements, in particular contact shoes, after the battery has been installed in the vehicle in order to connect the battery to the vehicle's electrical system. To protect against unintentional discharging, charging and/or short circuits, additional contact protection caps are typically applied to the battery poles, which must be removed after and/or during assembly of the battery. Alternatively or in addition, the battery poles can be isolated from the power supply for transport and assembly using a controllable circuit breaker in the battery.

Additional parts in or on the battery, such as contact protection caps or circuit breakers, result in additional parts costs and additional work for removing these protective measures. Furthermore, the contact protection caps can be lost during transport, so that there is no longer any protection against improper charging and/or discharging.

The present document deals with the technical task of providing a particularly efficient protection against contact, charging and/or discharging for a battery.

The object is solved by each of the independent claims. Advantageous embodiments are described inter alia in the dependent claims. It is pointed out that additional features of a patent claim dependent on an independent patent claim without the features of the independent patent claim or only in combination with a subset of the features of the independent patent claim can form a separate invention independent of the combination of all features of the independent patent claim, which can be made the subject of an independent claim, a divisional application or a subsequent application. This applies equally to the technical teachings described in the description, which can form an invention independent of the features of the independent patent claims.

According to one aspect, a battery is described which comprises a housing and battery poles arranged on the housing, of which at least one contactable battery pole is designed to be connected to a battery-external contact element. The battery poles can include a negative pole and a positive pole. In this case, the negative pole can be provided for being connected to ground, in particular via a battery-external contact element. The contactable battery pole can be the plus pole.

In a preferred example, the battery is designed as a battery for a motor vehicle. For example, the battery can have a nominal voltage of 12V or 48V. Furthermore, the battery can be a lead battery or a lithium-ion battery.

The battery also includes one or more (electrochemical) battery cells arranged in the housing, which are designed to cause a voltage (in particular the nominal voltage) at the battery poles when the one or more battery cells are electrically conductively connected to the battery poles. In this case, the negative pole of the battery (inside the housing) can be electrically conductively connected to the corresponding negative pole of the one or more battery cells. Correspondingly, the plus pole of the battery (inside the housing) can be electrically conductively connected to the corresponding plus pole of the one or more battery cells.

The battery is designed in such a way that the battery pole that can be contacted is only connected to the one or more battery cells in a galvanically conductive manner by connecting the battery-external contact element to the battery pole that can be contacted (without the action of a possibly electronic controller). In other words, the battery can be designed in such a way that it is only by connecting the battery-external contact element (e.g. via a direct mechanical coupling) that the contactable battery pole (within the housing) is electrically conductively connected to the one or more battery cells becomes. On the other hand, the battery is preferably designed in such a way that the battery pole that can be contacted is electrically isolated from the one or more battery cells if and/or as long as no battery-external contact element is connected to the battery pole that can be contacted.

A battery is thus described in which at least one of the battery poles is electrically connected the one or more battery cells (in particular from the corresponding pole of the one or more battery cells) of the battery is disconnected as long as the battery has not yet been connected (via contact elements). The galvanically conductive connection is then effected directly by connecting a contact element to the at least one contactable battery pole, so that the battery can be used for charging and/or discharging. In this way, reliable protection against contact, charging and/or discharging can be provided in an efficient manner.

If necessary, both battery poles of the battery can each be designed as a battery pole that can be contacted, in which case the connection to the one or more battery cells is only effected by connecting a contact element to the battery pole. In this way, the safety of the battery can be further increased.

The battery can have an internal pole which is arranged in the housing and which is electrically conductively connected to the one or more battery cells. The internal pole can have the same polarity as the corresponding contactable battery pole. The internal pole can have a displaceable and/or pivotable contact surface for making contact with the contactable battery pole.

The internal pole can be designed in such a way that the internal pole is electrically isolated from the battery pole that can be contacted, in particular by an air gap, if no battery-external contact element is connected to the battery pole that can be contacted. The internal pole can be held at a distance from the contactable battery pole, e.g. by a screw and/or by a spring. Protection against contact, charging and/or discharging can thus be provided in a reliable manner if and/or as long as the battery has not been connected (to or in a vehicle electrical system) and/or installed.

Alternatively or additionally, the internal pole can be designed in such a way that the internal pole is electrically conductively connected to the battery pole that can be contacted when the battery-external contact element is connected to the battery pole that can be contacted. In particular, the internal pole can be designed in such a way that the internal pole is only electrically conductively connected to the contactable battery pole when the external battery contact element is connected to the contactable battery pole (e.g. by a direct mechanical coupling between the connection mechanism of the battery-external contact element and the internal pole).

By providing at least one internal pole which is (permanently) connected to the one or more battery cells and which can be galvanically isolated from the contactable battery pole or galvanically conductively connected to the contactable battery pole, the selective connection of the contactable battery pole to which are effected in a particularly efficient and reliable manner in one or more battery cells when the battery-external contact element is connected.

The internal pole can have an electrically conductive contact surface which is arranged at a distance from a (corresponding) contact surface of the contactable battery pole arranged in the housing, in particular when no battery-external contact element is connected to the contactable battery pole. The contact surfaces can be held at a distance from one another, for example by a screw and/or by a spring.

The contact surface of the internal pole can also be designed to be moved toward the contact surface of the contactable battery pole located in the housing by connecting the external battery contact element to a part of the contactable battery pole located outside of the housing, so that the contact surfaces are connected to one another in a galvanically conductive manner . The contact surface of the internal pole can perform a pivoting movement and/or a translational movement. An internal pole designed in this way can selectively connect the contactable battery pole to the one or more battery cells in a particularly efficient and reliable manner.

The battery can include a screw that is acted on when the battery-external contact element is connected to the contactable battery pole. The screw can, for example, run from the outside through the contactable battery pole into the inside of the housing. The screw can be designed, as a result of the action on the screw, to connect the internal pole in a galvanically conductive manner to the battery pole that can be contacted, in particular by the screw moving the internal pole toward the battery pole that can be contacted.

A screw can enable movement of the internal pole in an efficient and reliable manner in order to bring about the selective connection of the contactable battery pole to the one or more battery cells.

The screw can also be designed to attach the battery-external contact element to the battery pole that can be contacted, so that the Battery-external contact element is electrically conductively connected to the contactable battery pole. The screw can thus possibly fulfill two functions that are effected simultaneously by acting on the screw. The action on the screw can simultaneously bring about the galvanically conductive connection of the contactable battery pole to the one or more battery cells and the galvanically conductive connection of the contactable battery pole to the battery-external contact element. In this way, the selective connection of the contactable battery pole to the one or more battery cells can be effected in a particularly efficient and reliable manner.

The internal pole may have a thread into which the screw is screwed. The screw can be turned in the thread of the internal pole as a result of the action when connecting the battery-external contact element, so that the internal pole is moved toward the battery pole that can be contacted.

Alternatively or additionally, the battery-external contact element can be connected by acting on a screw nut arranged on the screw. In this case, the nut can be arranged outside of the housing. The screw can be designed to move the internal pole towards the contactable battery pole as a result of the action on the screw nut. In this way, a movement of the internal pole as a result of the connection of the battery-external contact element can be effected in an efficient and reliable manner.

According to a further aspect, a (road) motor vehicle (in particular a passenger car or a truck or a bus or a motorcycle) is described which comprises the battery described in this document.

According to another aspect, a method for protecting a battery is described. The battery typically comprises a housing and battery poles arranged on the housing, of which at least one battery pole (referred to in this document as a contactable battery pole) is designed to be connected to a battery-external contact element (e.g. to a contact shoe). The battery can also include one or more battery cells arranged in the housing, which are designed to cause a voltage at the battery poles (and possibly a current across the battery poles) when the one or more battery cells are galvanically conductively connected to the battery poles.

The method includes causing the contactable battery pole to be galvanically conductively connected to the one or more battery cells only by connecting the battery-external contact element to the contactable battery pole. In this case, by connecting the battery-external contact element via a (direct) mechanical coupling, the contactable battery pole can be electrically conductively connected to the one or more battery cells.

It should be noted that the methods, devices and systems described in this document can be used both alone and in combination with other methods, devices and systems described in this document. Furthermore, any aspects of the methods, devices and systems described in this document can be combined with one another in a variety of ways. In particular, the features of the claims can be combined with one another in many different ways. Furthermore, features listed in brackets are to be understood as optional features.

• 1a ein beispielhaftes Fahrzeug mit einer Fahrzeugbatterie;
• 1b ein beispielhaftes elektrisches Bordnetz für ein Fahrzeug mit einer Fahrzeugbatterie;
• 2 eine beispielhafte Fahrzeugbatterie mit einem mechanisch trennbaren Batteriepol; und
• 3 ein Ablaufdiagramm eines beispielhaften Verfahrens zur Absicherung eines Batteriepols einer Batterie.

The invention is described in more detail below using exemplary embodiments. show it

• 1a an example vehicle with a vehicle battery;
• 1b an exemplary electrical system for a vehicle with a vehicle battery;
• 2 an example vehicle battery with a mechanically separable battery post; and
• 3 a flowchart of an exemplary method for securing a battery pole of a battery.

As explained at the outset, the present document deals with increasing the protection against contact, charging and/or discharging of a battery, in particular a vehicle battery. In this context shows 1a an exemplary vehicle 100 with a vehicle battery 106 which is designed to supply one or more electrical consumers 102 of the vehicle 100 with electrical energy. The battery 106 can, as in 1b shown, be part of an on-board electrical system 110 of vehicle 100 . The vehicle electrical system 110 can also include an energy source 103, in particular a generator, which is designed to provide electrical energy in the vehicle electrical system 110 from the outside.

2 shows an exemplary battery 106 with two battery poles 201, 202, in particular with a negative pole 201 and a positive pole 202. Between the battery poles 201, 202 (within the housing 200 of the battery 106) are one or meh rere battery cells 205 are arranged, which are designed to cause an electrical voltage between the battery poles 201, 202. The voltage can be in a low-voltage range, for example 60V or less, for example 48V or 12V.

A contact element 211, 212, in particular a contact shoe, can be connected to the battery poles 201, 202 in order to electrically conductively connect the battery 106 to the on-board electrical system 110. The battery 106 can be designed in such a way that a voltage is only present at the battery poles 201, 202 when the battery poles 201, 202 are connected to the contact elements 211, 212. In particular, the battery 106 can be designed in such a way that it is only when the contact elements 211, 212 are connected to the battery poles 201, 202 (or that only when a contact element 212 is connected to at least one battery pole 202) that a voltage is applied to the Battery poles 201, 202 is present.

in the in 2 The example shown is the battery pole 202, in particular the positive pole, separated by a gap 204 from an internal pole 203 of one or more battery cells 205 when no contact element 212 is connected to the battery pole 202. As a result, the battery pole 202 is galvanically decoupled from the one or more battery cells 205 and no voltage is present between the battery poles 202 of the battery 106 .

By connecting the contact element 212 to the battery pole 202, the battery pole 202 and the internal pole 203 are moved towards each other, in particular the internal pole 203 is moved towards the battery pole 202, so that an electrically conductive connection between the battery pole 202 and the one or more battery cells 205 is formed. As a result, there is a voltage between the battery poles 201, 202 as soon as the contact element 212 is connected to the battery pole 202.

A battery terminal 202, which can be decoupled from the one or more battery cells 205 within the housing 200 of the battery 106, and which can be coupled to the one or more battery cells 205 by connecting a contact element 212 within the housing 200, is also described in this document referred to as "contactable battery pole".

The internal pole 203 can, for example, have a threaded hole into which a screw 207 can be screwed, which runs from the outside through the battery pole 202 to the internal pole 203. For connecting the contact element 212 to the battery post 202 , the screw 207 can be screwed into the threaded hole of the internal post 203 so that the internal post 203 is attracted to the battery post 202 by the screw 207 . As a result, the gap 204 between the battery post 202 and the internal post 203 is reduced until the internal post 203 finally touches the battery post 202 (thus establishing a galvanically conductive connection).

In an alternative example, the internal post 203 can be fixedly connected to a screw 207 that is led out of the housing 200 of the battery 106 through the battery post 202 . The contact element 212 can have a screw nut that is screwed to the screw 207 so that the internal pole 203 is pressed by the screw 207 against the underside of the battery pole 202 in order to galvanically conductively connect the battery pole 202 to the one or more battery cells 205.

The integration of a mechanical switching element 203 into a battery 106, in particular into a battery pole 202, is thus described. When a cable, a cable lug and/or a contact part 212 is screwed tightly onto the battery pole 202, the switching element 203 closes an electrical contact with a corresponding screw 207 using a suitable mechanical construction, such as a contact part, a flexible busbar, etc. As a result, battery pole 202 is energized.

3 shows a flowchart of an exemplary method 300 for protecting a battery 106, in particular a low-voltage motor vehicle battery. The battery 106 comprises a housing 200 and battery poles 201, 202 arranged on the housing 200, of which at least one contactable battery pole 202 is designed to be connected to a battery-external contact element 212. The battery pole 202 that can be contacted can be the plus pole of the battery 106, for example. If necessary, both battery poles 201, 202 can be designed as contactable battery poles.

The battery 106 also includes one or more (electrochemical) battery cells 205 arranged in the housing 200, which are designed to cause a voltage at the battery poles 201, 202 when the one or more battery cells 205 are galvanically conductive with the battery poles 201, 202 are connected. The one or more battery cells 205 may be lead-based or lithium-ion based.

The method 300 includes causing 301 that the contactable battery pole 202 only by connecting the battery-external contact element 212 to the contactable battery pole 202 galvanically conductive with the one or more Battery cells 205 is connected. In particular, it can be achieved that the contactable battery pole 202 is electrically isolated from the one or more battery cells 205 (in particular from the corresponding pole of the one or more battery cells 205) if no battery-external contact element 212 is connected to the contactable battery pole 202. In this way, reliable protection against contact, charging and/or discharging can be provided.

Furthermore, the act of connecting the battery-external contact element 212 to the contactable battery pole 202 can 301 cause the one or more battery cells 205 (in particular the corresponding pole of the one or more battery cells 205) is electrically conductively connected to the contactable battery pole 202. As a result, the voltage of the one or more battery cells 205 is provided at the battery poles 201, 202 of the battery 106, so that the battery 106 can be charged or discharged via the battery poles 201, 202.

The measures described in this document can cause one or more battery poles 201, 202 of a battery 106 to be de-energized during transport and/or assembly. The one or more battery poles 201, 202 are only energized and/or electrically contacted during assembly (and directly through assembly) in a vehicle 100. In this way, unintentional or improper discharging and/or charging of the battery 106 outside of the vehicle 100 can be reliably prevented.

The present invention is not limited to the exemplary embodiments shown. In particular, it should be noted that the description and the figures are only intended to illustrate the principle of the proposed methods, devices and systems by way of example.

Claims (10)

battery (106) comprising - a housing (200); - Battery poles (201, 202) arranged on the housing (200), of which at least one contactable battery pole (202) is designed to be connected to a battery-external contact element (212); and - One or more battery cells (205) arranged in the housing (200) which are designed to cause a voltage at the battery poles (201, 202) when the one or more battery cells (205) are galvanically conductive with the battery poles (201, 202) connected; wherein the battery (106) is designed in such a way that the contactable battery pole (202) is only galvanically conductively connected to the one or more battery cells (205) by connecting the battery-external contact element (212) to the contactable battery pole (202). Battery (106) according to claim 1 , wherein - the battery (106) has an internal pole (203) which is arranged in the housing (200) and which is galvanically conductively connected to the one or more battery cells (205); and - the internal pole (203) is designed such that - the internal pole (203) is electrically isolated from the contactable battery pole (202), in particular by an air gap (204), if no battery-external contact element (212) on the contactable battery pole (202) is connected; and/or - the internal pole (203) is electrically conductively connected to the contactable battery pole (202) when the battery-external contact element (212) is connected to the contactable battery pole (202); and/or - only by connecting the external battery contact element (212) to the contactable battery pole (202) is the internal pole (203) electrically conductively connected to the contactable battery pole (202). Battery (106) according to claim 2 , wherein - the battery (106) comprises a screw (207) which is acted upon when the battery-external contact element (212) is connected to the contactable battery pole (202); and - the screw (207) is designed to connect the internal pole (203) to the contactable battery pole (202) in a galvanically conductive manner as a result of the action, in particular by the screw (207) connecting the internal pole (203) to the contactable battery pole (202 ) moved there. Battery (106) according to claim 3 , wherein - the internal pole (203) has a thread into which the screw (207) is screwed; and - the screw (207) is turned in the thread of the internal pole (203) as a result of the action when connecting the battery-external contact element (212), so that the internal pole (203) is moved towards the contactable battery pole (202). Battery (106) according to any one of claims 3 until 4 wherein - the connection of the battery-external contact element (212) is effected by acting on a screw nut arranged on the screw (207); and - the screw (207) is designed to move the internal pole (203) towards the contactable battery pole (202) as a result of the action on the screw nut. Battery (106) according to any one of claims 3 until 5 , wherein the screw (207) is designed to fasten the battery-external contact element (212) to the contactable battery pole (202), so that the battery-external contact element (212) is electrically conductively connected to the contactable battery pole (202). Battery (106) according to any one of claims 2 until 6 , wherein the internal pole (203) has an electrically conductive contact surface, - which is arranged at a distance from a contact surface of the contactable battery pole (202) arranged in the housing (200), in particular when there is no battery-external contact element (212) on the contactable battery pole (202) connected; and - which is designed to move towards the contact surface of the contactable battery pole (202) arranged in the housing (200) by connecting the battery-external contact element (212) to a part of the contactable battery pole (202) arranged outside of the housing (200). to be, in particular by a pivoting movement and / or by a translational movement, so that the contact surfaces are galvanically connected to each other. Battery (106) according to any one of the preceding claims, wherein - The battery (106) is designed as a battery for a motor vehicle (100); and or - the battery (106) has a nominal voltage of 12V or 48V; and or - the battery (106) is a lead-acid battery or a lithium-ion battery. Battery (106) according to any one of the preceding claims, wherein - The battery poles (201, 202) comprise a negative pole and a positive pole; - The negative pole is intended to be connected to ground, in particular via a battery-external contact element (211); and - the contactable battery pole (202) is the positive pole. Method (300) for protecting a battery (106); the battery (106) comprising: a housing (200); battery poles (201, 202) arranged on the housing (200), of which at least one contactable battery pole (202) is designed to be connected to a battery-external contact element (212); and one or more battery cells (205) arranged in the housing (200) which are designed to bring about a voltage at the battery poles (201, 202) when the one or more battery cells (205) are galvanically conductive with the battery poles (201, 202) connected; the method (300) comprising - Cause (301) that the contactable battery pole (202) is electrically conductively connected to the one or more battery cells (205) only by connecting the battery-external contact element (212) to the contactable battery pole (202).

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