DE202018100239U1 - Battery power supply for an industrial truck used in a hazardous area - Google Patents

Abstract

Battery power supply (1) for a used in a hazardous area industrial truck (8), with a, a housing body (47) and a lid (4) having housing (2), wherein the housing body (47) has a receiving space (48) for receiving a Battery trough (3) having an interior space (20) with a traction battery (25) arranged therein, and the cover (4) with securing means (53) releasably on the housing body (47) can be fixed and the battery tray (3) a battery trough lid ( 49) and a floor (26) with walls (17, 18) extending away from the floor (26), characterized in that at least one wall (17, 18) in an area adjacent to the floor (26) forms a wall (17). 17, 18) to the interior (20) passing through recess (19).

Description

The present invention relates to a battery power supply for a used in a hazardous area forklift, having a, a housing body and a lid having a housing, wherein the housing body has a receiving space for receiving a battery trough having an interior with a traction battery disposed therein, and the lid releasably securable with securing means on the housing body and the battery tray has a battery tray lid and a bottom having away from the ground walls, according to the preamble of claim 1.

Electromotive-powered industrial trucks are often used in hazardous areas, such as in the chemical or pharmaceutical industry and such industrial trucks may only be operated with power sources that are approved for use in accordance with applicable types of protection, such as the ATEX directive, and in particular by the device categories 2G or 2D the ATEX Directive 2014/34 / EU are certified.

Such industrial trucks must therefore be operated with sources of electrical energy, on the one hand provide sufficient power available and on the other hand stored in housings that are approved according to the aforementioned provisions. As sources of electrical power so far mainly lead acid batteries are used, which are arranged in a corresponding housing.

A major drawback of such batteries based on lead-acid batteries is that they are not suitable for a multi-shift operation with a single battery power supply for a day shift of the industrial vehicle, since they have too little capacity and it is therefore necessary to provide several such battery power supplies per truck which have to be exchanged during a day shift and then also have to be reloaded.

For the charging operation of such battery power supplies based on lead acid batteries separate premises are required by the hazardous operating area, which must be connected to a fresh air supply due to the emerging during loading acid fumes and the risk of the formation of oxyhydrogen gas and must be provided with an exhaust system, which on the one hand the handling effort significantly increased and on the other hand also contributes to an increase in the operating costs of such equipped industrial trucks.

If such battery power supplies are used on lead acid base, it is usually necessary to have three to four battery power supplies available for one day shift per industrial truck, from which the significant expense mentioned above immediately becomes apparent.

It is therefore desirable to reduce this expense by using other sources of electrical power.

Based on DE 10 2004 008 569 A1 a battery power supply for underground mining has become known, which has a pressure-resistant battery case with lithium battery cells arranged therein and whose characteristic feature is that an intrinsically safe circuit for overcurrent limiting and / or overvoltage limiting is provided in the battery housing. The battery housing known therefrom has a battery tray and an additional housing coupled thereto, in which the intrinsically safe circuit is arranged, being arranged in the pressure-resistant battery housing lithium battery cells, from the series of lithium-ion battery cells, lithium polymer battery cells or lithium -Abs are selected with a liquid electrolyte.

The wall thickness of the surrounding walls of the battery case and the lid and the screw connection between said components are designed so that the battery case pressure and gas-tight remains closed, when an explosion occurs in the interior of the battery case with a certain maximum explosion pressure, which occurs after the for lithium battery cells expected maximum bursting pressure.

Based on EP 2 945 215 B1 has become known a traction battery, which is intended for industrial trucks and makes use of battery cells based on the lithium-polymer technology, lithium-cobalt dioxide technology, lithium-manganese technology, lithium titanate technology or lithium iron phosphate Technology based. In addition, this known traction battery is provided with a battery management system for data exchange with the industrial truck and / or a charger. However, this known traction battery has no properties that would allow an indication of their use in potentially explosive atmospheres.

Proceeding from this, the present invention seeks to provide a battery power supply for used in explosive area industrial trucks, which on the one hand for use in gas and dust zones is permitted and on the other hand reduces the handling described above and also designed so that in case of danger in the housing of the battery power supply unexpectedly high explosion pressures do not lead to bursting of the housing. Also, an industrial truck should be provided with such a battery power supply.

To solve this problem, the invention has the features specified in claim 1. Advantageous embodiments thereof are described in the further claims. The created according to the invention industrial truck has the features specified in claim 14.

The invention provides a battery power supply for a used in a hazardous area industrial truck, with a, a housing body and a lid having a housing, wherein the housing body has a receiving space for receiving a battery trough having an interior with a traction battery disposed therein, and the lid with Securing means releasably secured to the housing body and the battery tray has a battery tray lid and a bottom with extending away from the ground walls, wherein at least one wall in an area adjacent to the floor has a wall passing through the wall to the interior recess.

With the battery power supply according to the invention, it is achieved that at an occurring in the battery tray explosion of the traction battery used in the explosion pressure on the Zünddurchschlagicher trained at least one recess in a floor adjacent area on at least one wall of the battery trough is reduced so far that a bursting of the battery trough and / or an uncontrolled lifting or loosening of the lid is avoided by the battery tray.

The explosion pressure can be prevented in this way by a pressure release from the interior or space of the battery trough in the vicinity of the battery trough without the escape of any flames due to the explosion inside the battery trough to the outside of the battery trough, so that there is no longer the risk that the battery trough bursts uncontrollably and / or the lid of the battery tray in an uncontrolled manner partially or completely.

By arranging the at least one recess on a wall of the battery trough in a region adjacent to the bottom, it is achieved that a superposition of an explosion wave in the interior of the battery trough to form a superposition wave and thus an explosion wave with a higher pressure than the pressure of the primary explosion wave Pressure peak can be reduced to a pressure below the bursting pressure of the battery trough and also that acting on the lid of the battery trough from the interior of the battery trough force application does not lead to an uncontrolled lifting or loosening the lid from the battery trough. The configuration also means that relaxes by the relaxation of the higher pressure to a level below the bursting pressure such a burst pressure not explosively uncontrolled outside of the battery trough, which could lead to the fact that the battery trough surrounding the housing of the battery power supply would risk burst, so that an explosion protection against the bursting of the housing of the battery power supply would no longer exist. The controlled release of the higher pressure within the housing of the battery power supply eliminates the risk of the housing of the battery power supply bursting.

Also, this controlled pressure release within the housing of the battery power supply ensures that the cover of the housing of the battery power supply remains in a predetermined manner on the housing body of the housing and does not enter the situation that sets a gap between the lid of the housing and the housing body which would allow permeation of oxygen from the environment in the interior or receiving space of the housing. Such a seepage of oxygen could occur during an explosive spreading of the bursting pressure within the receiving space by a gap formation between the cover and the housing of the battery power supply, which is prevented by the configuration according to the invention.

It is provided according to a development of the invention that the bottom of the battery trough in a plan view has a rectangular configuration with long sides and transverse sides and the longitudinal sides have a longitudinal extent which is greater than the longitudinal extent of the transverse sides and the walls to form the interior at an angle extend to the bottom of this away and arranged on the transverse sides of walls disposed in the region of the middle of the longitudinal extent of the respective wall passing through recess and arranged on the longitudinal sides walls each having two penetrating recesses arranged at opposite end portions of the longitudinal sides of the respective wall are.

It has become part of the development of the battery power supply according to the invention namely shown that in a worst case assumed scenario explosion in the interior of the battery trough forms a superposition shaft or superposition shaft from the initial explosion wave, which is formed by between the bottom of the battery trough and the lid of the battery trough back and forth explosion waves, and the overlay shaft leads to a massive pressure increase relative to the pressure of the initial explosion wave, which could lead to unintentional lifting of the lid from the battery tray and thus to an uncontrolled escape of the overlay pressure from the battery tray when hitting the lid of the battery trough.

By forming the at least one recess in a wall of the battery trough adjacent to the bottom of the battery trough formed by the overlay shaft excessive pressure or overlay pressure from the interior of the battery can be relaxed in a harmless manner outside the interior or receiving space of the battery trough, so that the risk of Bursting of the battery trough and / or the lifting of the lid from the battery tray can be minimized or eliminated. It has been shown in particular that by the formation of a respective recess on each wall on the two transverse sides of the battery trough and by the formation of two recesses on each wall on the two longitudinal sides of the battery trough the excessive internal pressure in the interior of the battery trough as far as harmless after can be relaxed outside of the battery trough, so that the risk of uncontrolled loosening the lid of the battery trough and / or the formation of an unintentional gap between the lid of the battery trough and the peripheral walls of the battery can be avoided.

The relaxing from the battery tray to the outside pressure remains in the interior of the housing, ie in the interior between the housing body and cover of the housing of the battery power supply, so that on the formed without gaps in the explosion-hazardous environment flameproof enclosure battery power supply no explosion gases and no the explosion caused flames can escape to the outside.

It has also been found that this configuration eliminates the risk that between the housing body and the lid of the housing body, a gap opens, the subsequent flow of oxygen from the environment of the housing in the interior of the housing and in the interior of the battery trough would promote what can be avoided in spite of an explosion in the interior of the battery trough in the retention of the lid on the battery tray and it comes to an immediate suffocation of forming by the explosion flame front and in this way the escape of a flame front from the interior of the battery trough and the interior of the housing to the outside of the housing can be avoided.

It is also provided according to a development of the invention that the recesses are formed as the respective wall passing through rectangular wall openings. This facilitates, for example, the production of the walls of the battery trough, since the wall openings can be formed for example by means of a water jet cutting process, since the walls of the battery can be made of a metallic material, in particular a steel alloy and in this way the recesses cost even with walls with greater wall thickness can be produced.

It is also provided according to a development of the invention, that the recesses are formed at the bottom end portion of the interior of the battery trough and have a total area which reduces a resulting within the scope of a type examination of the housing by a triggered in the housing test explosion test explosion internal pressure prevailing in the battery trough admission internal pressure which is smaller than an explosion pressure opening the battery tray and / or the sealed case.

As part of the type examination of the housing of the battery power supply according to the invention, the battery tray was filled with a test gas and caused a controlled explosion in the interior of the battery trough by means of an electric ignition and the resulting explosion internal pressure in the interior of the battery trough at several points along the height direction of the battery trough measured distributed and thereby It has been found that sets up a layered pressure distribution in the interior of the battery trough, which is due to the fact that the explosion wave repeatedly moves back and forth between the bottom and the lid of the battery trough and in this way by the reflections on the ground and the Cover of the battery tray to form a superposition wave comes, which has a much higher pressure level than the pressure level of the initial explosion wave.

By arranging the at least one recess and in particular the recesses on the transverse walls and longitudinal walls of the battery trough at the points specified above, the superposition pressure in the interior of the battery trough can be relaxed to the outside of the battery trough be, without causing the risk of a gap surface of the housing of the battery power supply opening uncontrolled deformation or destruction of the battery trough and the overlay shaft could thus leave the interior of the battery trough and the interior or receiving space of the housing of the battery power supply according to the invention in an uncontrolled manner.

It is also provided according to a development of the invention that the recesses are arranged at the bottom end portion of the interior of the battery trough above the ground in an area where an overlay wave occurs, which is caused by an explosion triggered in the housing, which also by an explosion could be caused by battery cells of the traction battery. This configuration means that the maximum pressure occurring through the overlay shaft in the region of the bottom of the battery trough can be released from the interior of the battery trough without any flame front being able to leave the interior of the battery trough via the ignition-puncture-proof recesses.

It has been shown that the flame front, which arises due to the explosion in the interior of the battery trough, due to the pressure increase in the interior of the battery trough in the region of the bottom and thereby induced oxygen distribution with an accumulation of oxygen in the lid in the upright battery tray after moves up, so directed away from the recesses formed at the bottom of the battery trough and thus it does not come to an outward penetration of the flame front of the battery case.

Due to the configuration of the battery trough explained in more detail below, the flame front extinguishes and is thus held in the interior of the battery trough without penetrating to the outside.

It is provided according to a development of the invention that between a housing body facing the lid surface and the lid facing surface of the housing body is a finely machined slit surface with a predetermined gap surface width and a center roughness smaller or smaller than 6.3 microns is formed. This configuration leads to the already-mentioned extinction of the flame front, as over this finely machined gap surface with a predetermined gap surface width and a Mittenrauwert less than or equal to 6.3 microns backflow of oxygen from the environment into the interior of the housing and / or the battery can is avoided and thus the Flame front in the interior goes out.

It is also provided according to a development of the invention that the cover on the housing body of the housing by means of a plurality of screw is releasably fixed and the screw are provided along an outer circumferential line of the cover extending and are arranged at a predetermined distance from each other. The predetermined spacing of the screw connections is, in particular, a distance in the range of 30 to 80 mm, in particular 50 to 65 mm, between the screw connections, and as a result a closing force in the area of the gap surface is achieved which prevents an afterflow of oxygen into the interior space. causing the flame front to go out.

It is also provided according to a development of the invention that between the receiving space and an underside of the battery tray cover a detachable festoonable on the battery tray intermediate cover is provided, which forms a receiving space between an upper side of the intermediate cover and the underside of the battery can lid and is designed to receive an electronic circuit ,

With this configuration it is achieved that in the battery tray a separate from the battery cells of the traction battery receiving space is formed, which is adapted to receive an electronic circuit or board, for example, for communication or data exchange between the state of the battery cells monitoring sensors and a controller or control device of the industrial truck and / or an external charger for charging the battery cells is used.

It is also provided according to a development of the invention that the battery power supply and in particular the battery tray is provided with cable glands for providing an electrical charging connection for charging the traction battery and an electrical power connection for providing electrical energy for the industrial truck.

The cable glands may be type-tested cable glands, which must be approved and maintained as part of an examination of the battery power supply according to the invention. Similarly, such cable glands can also be provided with an electrical charging connection for charging the traction battery and an electrical power connection for providing electrical energy for the industrial truck on the battery tray.

It is also provided according to a development of the invention that the battery power supply a switchable with a contactor load circuit for the operation of the industrial truck and a switchable with a contactor charging circuit for charging the traction battery has. In this case, a configuration is possible, which switches the load circuit for the operation of the industrial truck, ie the driving of the industrial truck, the lifting or lowering of load transport means of the industrial truck by means of a contactor voltage as soon as by means of a contactor of the charging circuit for feeding a charging current is released into the battery cells , In this way, a simultaneous operation of the industrial truck and charging the battery cells is prevented.

It is also provided according to a development of the invention that the battery power supply has an externally switchable and coupled with the contactors connection device such that the external circuit or externally triggered circuit alternately disconnects the load circuit voltage and the charging circuit turns on in such a way that the load circuit when switched charging circuit is voltage-free, whereby the above-mentioned simultaneous operation of the industrial truck and charging the battery cells of the battery power supply is avoided.

It is also provided according to a development of the invention that the battery power supply has an interface device in the form of a particular CAN bus interface device for exchanging data and / or signals between the traction battery functionally coupled electronic circuit and an external charging device for charging the traction battery , This configuration enables a master-slave configuration between the traction battery and the external charger, so that, for example, state data of the battery cells are transmitted to the external charger via the electronic circuit device and so a charge balancing method or charge balancing method for charging and / or operation of the battery cells of the traction battery is possible.

It is also provided according to a development of the invention that the traction battery is formed by a plurality of Lithiumeisenphosphatzellen, which are arranged substantially parallel to the bottom of the battery trough and between the cells are provided empty spaces for passage of gaseous fluid from the interior of the battery trough to the recess , This configuration makes it possible that by the parallel arrangement of the particular cylindrically shaped lithium iron phosphate cells between the housing bodies of the battery cells each have a void or free space which is available for the passage of the overlay shaft towards the recess or the recesses in the region of the bottom of the battery trough, so that the superposition of the shaft can move to the recess or the recesses and can take place via the recess or the recesses of the pressure reduction already described above.

Finally, the invention also provides an industrial truck with at least one electrically actuated drive device for driving the industrial truck and / or moving a load, wherein the industrial vehicle has a battery power supply, as has been described above. The industrial truck is intended in particular for operation in a hazardous area.

The industrial truck can be, for example, a self-propelled forklift vehicle, which is designed to drive the truck and lift or lower the load with a lifting device of the truck and for driving the vehicle or manipulating the load electrical energy by means of the above Battery power supply is provided.

The invention will be explained in more detail below with reference to the drawing. This shows in:

1 a perspective view of a battery trough of the battery power supply according to an embodiment according to the present invention;

2 a side view of the battery trough after 1 ;

3 a front view of the battery trough after 1 ;

4 a top view from above of a provided for assembly on a housing body of the housing of the battery power supply cover;

5 a perspective view of the battery trough;

5A a perspective view of the housing body of the housing of the battery power supply;

6 a cross-sectional view along the section line VI-VI according to 2 the drawing;

7 an exploded perspective view of the battery trough with traction battery disposed therein;

8th a side view of an industrial truck in the form of a forklift with arranged battery power supply according to the invention; and

9 a perspective view of the arranged in the housing of the battery power supply battery trough without the lid of the housing.

1 The drawing shows a perspective view of a battery trough 3 a battery power supply 1 according to an embodiment according to the present invention.

The most general in 9 the drawing shown battery power supply 1 has a housing 2 with a housing body 47 on, which one closer still by means of 5 the drawing apparent battery tray 3 in a recording room 48 ( 5A ) and a closer still by means of 4 , the drawing apparent cover 4 can record.

The battery tray 3 has a battery trough lid 49 ( 7 ) with cable glands 5 in the form of a cable gland 6 for providing a negative pole and a cable gland 7 for providing a positive terminal for the electrical power connection for providing electrical energy for an industrial truck 8th , which is closer to 8th the drawing apparent forklift 9 can act.

Similarly, on the battery tray lid 49 another cable gland 10 for providing a charging socket for connecting a negative pole and a cable gland 11 for providing a charging socket for connecting a positive pole of a charger not shown for charging the traction battery 25 intended.

In addition, on the battery tray lid 49 an interface device shown only schematically 12 provided, which in the illustrated embodiment, a seven-pin data connector 13 for connecting a CAN bus communication connection between an electronic circuit device 14 , which is closer to 6 the drawing is apparent, and the charger is provided and a seven-pin data connector 15 which is used to connect a CAN bus communication connection between the electronic circuit device 14 and the industrial truck 8th is trained.

The battery tray 3 has a floor 16 on, as for example by means of 1 and 5 the drawing is shown, from which at right angles towards the battery tray lid 49 each directed two transverse side walls 17 and two longitudinal side walls 18 extend, wherein in the illustrated embodiment of the battery trough 3 the transverse side walls 17 have a lower longitudinal extent than the longitudinal side walls 18 ,

As it is based on 1 the drawing can be seen, has the battery tray 3 in the illustrated embodiment on the longitudinal side wall 17 in a ground 16 adjacent area a recess 19 that as a wall breakthrough 21 is formed and separated from an area or space outside the battery trough 3 into the battery tray 3 trained interior 20 (please refer 6 ).

Similarly, on the transverse side wall 17 which due to the in 1 selected perspective view is not apparent in the area of the soil 16 of the battery trough 3 also a recess 19 formed and indeed in the form of a wall breakthrough 21 ,

Also the recess 19 the transverse side wall 17 extends from an area or space outside the battery trough 3 into the battery tray 3 trained interior 20 into it.

1 The drawing also shows that the longitudinal side wall 18 two recesses 19 in the form of wall breakthroughs 21 owns, again in the area of the soil 16 of the battery trough 3 and in particular at opposite end regions 22 the long side 18 , where the end areas 22 in the illustrated embodiment of the battery trough 3 to the respective transverse side walls 17 adjoin.

The due to the in 1 the drawing selected perspective not visible long side 18 also has two recesses 19 in the form of wall breakthroughs 21 on, in the manner described above corresponding manner at the respective end portions of the longitudinal side 18 are formed and also from an area or space outside the battery trough 3 to the interior 20 of the battery trough 3 extend.

2 The drawing shows a side view of the battery trough 3 and a longitudinal side wall 18 with those in the area of the soil 16 of the battery trough 3 trained two recesses 19 , as already described above.

In the illustrated embodiment of the battery trough 3 the battery power supply 1 own the recesses 19 each a rectangular configuration with a longitudinal side extension of 130 mm and a height dimension of 25 mm, wherein the recesses 19 each a lower edge 23 show, from the bottom 24 of battery box 3 So the bottom of the floor 16 is viewed from each 20 mm apart, so that adjusts the configuration already described above, that the recesses 19 each in a ground 16 adjacent area are formed.

3 The drawing shows a front view of the battery trough 3 with the transverse side wall 17 located in the area of the bottom or the bottom of the transversal sidewall 17 a rectangular recess 19 having a longitudinal extent of 130 mm and a height dimension of 25 mm and also has a lower edge 23 that is from the bottom 24 of the soil 16 has a distance of 20 mm.

As already explained above, the opposite transverse side wall also has 17 a recess 19 and the opposite longitudinal side wall 18 has two recesses 19 on, on the one hand in the middle of the longitudinal extent of the transverse side wall 17 and on the other hand at the two end regions 22 the longitudinal extent of the longitudinal side wall 18 are arranged.

The configuration and placement of the respective recesses 19 in the form of wall breakthroughs 21 on the longitudinal side walls 18 and the transverse side walls 17 is chosen so that the pressure due to a possible explosion in the interior 20 of the battery trough 3 arranged traction battery 25 (please refer 6 the drawing) through the recesses 19 can be relaxed to a residual pressure level, which is so low that the housing 2 the battery power supply 1 is not opened by the explosion in an unintentional manner, so for example, bursts, and the lid 4 on the housing body 47 remains, so not from the housing body 47 is lifted off or between the lid 4 and the housing body 47 the battery power supply 1 forms a gap, the penetration or flow of oxygen into the receiving space 48 of the housing 2 would allow.

The configuration and placement of the respective recesses 19 on the battery tray 3 is particularly chosen so that there is a pressure increase in the interior 20 of the battery trough 3 the battery power supply 1 due to an explosion in the interior 20 arises, and through one between the ground 16 and the battery tray lid 49 reciprocating superposition shaft or superposition shaft arises, not for forcible and unintentional opening of the housing 2 leads, as a through the overpressure wave in the area of the soil 16 of the battery trough 3 resulting pressure increase or pressure peak targeted by the thus configured and placed recesses 19 can be reduced to a residual pressure level, which the housing 2 the battery power supply 1 can remain intact in the desired manner, so no openings or gaps on the housing 2 emerge, which is a spreading of a flame front from the receiving space 48 of the housing 2 would enable out. An escape of a flame front from the interior 20 of the battery trough 3 out through the recesses 19 is thereby prevented that the recesses 19 in the area of the soil 16 of the battery trough 3 are arranged, as has already been explained above.

4 , Drawing shows a top view from above on the lid 4 of the housing 2 ,

As it is readily apparent, are located at the top 26 of the lid 4 also cable glands 6 . 7 . 10 . 11 arranged to lead out the cables for charging the battery and the power supply to the industrial truck 9 are provided and three more cable glands 55 arranged, which may be cable glands Exd and via the leads for connection to the data connectors 13 and 15 and the pilot contact 45 on the battery tray lid 49 can be arranged for data exchange and communication. A variety of holes or openings 27 are on the lid 4 provided along an outer circumferential line 28 of the lid 4 are arranged running and arranged at a predetermined distance from each other, wherein this distance in the illustrated embodiment of the battery power supply 1 or the lid 4 has a value of 55 to 65 mm. All cable glands mentioned in this document may be cable glands intended for use in potentially explosive atmospheres.

In the holes 27 can be a plurality of in 9 the drawing shown bolts 53 which are used in threaded holes 29 on an upper flange surface 30 of the housing body 47 can intervene, as in 9 the drawing is shown.

The flange surface 30 of the housing body 47 and an associated flange surface or cover surface 31 at the bottom of the lid 4 are finely machined, so that between the flange 30 and the lid surface 31 a finely machined gap surface 33 to 9 adjusts the drawing, which has a center roughness of 6.3 microns and a gap surface width of 30 mm. The bolts 53 be with a high preload force with the threaded holes 29 bolted and the finely machined splitting surface 33 ensures that in the event of an explosion in the interior 20 of battery box 3 a flame front not through the gap surface 33 through towards the outside of the battery case 2 can spread and an afterflow or inflow of oxygen through the finely machined nip 33 in the recording room 48 and interior 20 is avoided and due to the oxygen consumption in the interior 20 towards the lid 4 propagating flame front the flame front automatically extinguished.

6 The drawing shows a sectional view of the battery trough 3 according to section VI-VI 2 the drawing.

The battery tray 3 has a floor 16 with longitudinal sides arranged thereon 18 on, in which the recesses 19 in the form of wall breakthroughs 21 are formed, extending from outside the battery trough 3 to the interior 20 extend.

In the interior 20 is located in 6 the drawing only schematically illustrated traction battery 25 arranged, which in the following in more detail with reference to 7 the drawing is explained.

The arrangement of the traction battery 25 in the interior 20 is chosen so that between the outer surfaces of the traction battery 25 and the recesses 19 a free space or white space 34 remains, which is spread by an explosion in the interior 20 triggered pressure wave towards the recesses 19 towards. In this way it is achieved that also a superposition wave in the direction of the recesses 19 can spread out and triggered by the superposition wave pressure amplitude by a partial pressure reduction between the interior 20 and the environment of the battery trough 3 in the recording room 48 of the housing 2 can be degraded, so in the interior 20 and recording room 48 a residual pressure level remains lower than a predetermined bursting pressure of the battery case 2 and thus bursting of the battery case 2 or an area-wise bursting of the battery case 2 and an uncontrolled release of the lid 4 of the battery case 2 is avoided.

As it is based on 6 and 7 The drawing is also apparent, is between the interior 20 and the bottom 35 of the battery tray lid 49 on the battery tray lid 49 releasably fixable and based on 7 the drawing closer apparent intermediate cover 36 arranged, a reception room 37 between the top 38 of the intermediate lid and the bottom 35 of the battery tray lid 49 formed. The intermediate cover 36 can by means of schematically illustrated screw 50 on the long sides and transverse sides of the battery trough 3 be set and the battery tray lid 49 can by means of schematically illustrated screw 51 on the battery tray 3 be determined.

In the recording room 37 may be the electronic circuit device or circuit board 14 can be arranged, which has already been explained above and a circuit for monitoring the condition of the traction battery 25 or the battery cells of the traction battery 25 and simultaneously via one on the data connector 13 arranged pilot contact 45 can be switched so that, for example by means of a circuit-integrated contactor 43 for the load circuit and a contactor integrated in the circuit 44 for the charging circuit or by means of the circuit switchable contactors 43 . 44 the load circuit for the operation of the industrial truck 8th can be switched without voltage and the charging circuit for the recharging of the traction battery can be switched through such that the load circuit is disconnected when the charging circuit is switched on and an operation of the industrial truck 8th and charging the traction battery at the same time 25 is avoided.

7 The drawing shows an exploded perspective view of the battery trough 3 with traction battery arranged therein 25 , The traction battery 25 has a variety of lithium iron phosphate cells LiFePO ₄ 39 on, each as a cylindrical body 40 are formed and between the cells 39 each empty space or free space 41 are formed, which serve the passage of the above-described multiple pressure wave, passing through the voids 41 through towards the recesses 19 can spread and in this way the already mentioned partial pressure reduction from the interior 20 towards the area outside the battery trough 3 can take place.

5A The drawing shows a perspective view of the housing body 47 of the housing 2 the battery power supply 1 with the at the top of the case body 47 formed finely machined flange surface 30 and the multitude of threaded holes 29 with which the in 4 the lid shown in the drawing 4 by means of a screw engagement of the in 9 the screw shown in the drawing 53 in the threaded holes 29 can be set releasably.

9 The drawing shows a perspective view of the battery power supply 1 with the one in the recording room 48 arranged battery tray 3 , wherein in the selected representation of the lid 4 of the housing 2 the battery power supply 1 was omitted. Due to the arrangement of the cover 4 on the flange surface 30 the cleavage surface already mentioned above forms 33 out, which is an afterflow of oxygen into the interior 20 of the battery trough 3 prevents, causing an explosion in the interior 20 resulting flame front automatically extinguished by the consumption of oxygen and not outside the case 2 the battery power supply 1 can escape. The outer walls of the battery trough 3 form to the inner walls of the housing body 47 one space each 54 out, which serves as an expansion chamber for the pressure reduction from the interior 20 of the battery trough 3 serves.

8th the drawing shows one with the battery power supply according to the invention 1 provided forklift 9 , which is provided as an industrial truck for operation in a hazardous area of an industrial plant or the like.

The forklift 9 can by means of the battery power supply 1 be moved by electric motor and the load-carrying means 42 can by means of a schematically illustrated electric drive motor 46 of the forklift 9 be raised and lowered by electric motor. The electrical energy to operate the forklift 9 is doing by means of the battery power supply according to the invention 1 characterized in that the capacity of the battery power supply 1 for an entire day shift of the industrial truck 8th is sufficient and therefore there is no need during the entire shift, the battery power supply 1 a recharging the traction battery 25 to undergo.

The battery power supply according to the invention is intended for use in a hazardous area and meets the aforementioned types of protection and is especially for the device category 2G and 2D after ATEX Directive 2014/34 / EU approved and intended for use in zones of gas and dust. In particular, it complies with the provisions of explosion group II and its subgroups IIA, IIB and IIB + H ₂ and is characterized in particular by the fact that a superposition wave occurring due to a possible explosion in the housing of the battery power supply does not lead to the housing bursting, but rather with the Overlay wave accompanying excessive pressure to a residual pressure level is relaxed, which does not lead to destruction of the housing and in particular not to the fact that the cover of the battery case is opened or torn off and thus explosion protection would no longer exist.

In the context of test explosions carried out for test purposes of the battery current supply according to the invention with an explosive gas mixture, it has been shown that pressure spikes of 21.8 bar have occurred in the interior of the housing due to the superimposition of pressure waves and these pressure peak values are reduced to a value of under 8 bar could be lowered and therefore a bursting of the housing and accidental loosening of the lid of the housing could be avoided, so that the explosion protection could be maintained according to the task.

In addition, the inventive design of the battery power supply also ensures that weight plates or ground plates, which were previously required for increasing the stability with known Batteriestromversorgungen forklift trucks, can be omitted.

The cover of the housing of the battery power supply according to the invention is characterized by type-tested cable glands of equipment category 2G / 2D according to the above-mentioned ATEX directive, by which both the battery cables for charging the traction battery and the battery cables for energy supply for the industrial vehicle are performed. Through the cable glands, communication lines, CAN bus lines or lines for the transmission of data and / or signals between the traction battery and / or an electronic circuit device of the battery power supply according to the invention and external devices, circuits or devices can be performed and also lines for providing electrical energy for electric drive motors of a material handling vehicle.

The intended for use with the battery power supply according to the invention Lithiumeisenphosphatzellen provide in comparison to previously used lead-acid batteries for a considerable gain in the provided electrical capacity of the battery power supply, so that, for example, a capacity of about 200 ampere hours can be kept.

The load circuits of the traction battery are divided into a controlled by a contactor load circuit for driving the truck and lifting and lowering a lifting device of the industrial truck and a load circuit for charging the traction battery, which is secured by a contactor. Both load circuits are technically separated so that the forklift truck can not be moved while the traction battery is being charged. It is also ensured that the provided on the battery power supply connection means for charging the traction battery during operation of the traction battery are de-energized to dispense electrical energy for the operation of the industrial truck.

About a provided on a connection device of the battery power supply pilot contact of the charger is taken to ensure that a charge circuit for the traction battery is closed via the operation of a charging contactor or contactor, a contactor is switched off the load circuit for delivering electrical energy to the truck and thus the charge the traction battery is possible, a simultaneous discharge of the traction battery but via the load circuit is no longer possible.

By closing the pilot contact, data exchange is initiated via the aforementioned CAN bus communication interface between the electronic circuitry of the battery power supply and an external charger, so that a charge cycle corresponding to the state of charge of the lithium iron phosphate cells provided for forming the traction battery is performed using a charge balancing method can.

The finely machined gap surface formed between the cover and the housing of the battery power supply ensures that an afterflow or inflow of oxygen into the interior or receiving space of the housing in the case of the formation of a flame front after an explosion within the battery trough is prevented and thus the flame front extinguishes automatically ,

With regard to the features of the invention which are not explained in greater detail above, reference is expressly made to the claims and the drawings.

LIST OF REFERENCE NUMBERS

1

Battery power supply

2

casing

3

battery tray

4

cover

5

Cable gland

6

Cable gland

7

Cable gland

8th

Industrial truck

9

fork-lift truck

10

Cable gland

11

Cable gland

12

Interface device

13

data connector

14

Circuit means / PCB

15

data connector

16

ground

17

Transverse side wall

18th

Longitudinal side wall

19

recess

20

inner space

21

Wall opening

22

end

23

Lower edge

24

bottom

25

traction battery

26

top

27

drilling

28

Outer circumferential line

29

threaded hole

30

flange

31

cover surface

32

end regions

33

cleavage face

34

Space / space

35

bottom

36

intermediate cover

37

accommodation space

38

top

39

Lithium iron phosphate cells

40

body

41

Space / space

42

Load handling devices

43

contactor

44

contactor

45

pilot contact

46

drive motor

47

housing body

48

accommodation space

49

Battery container lids

50

screw

51

screw

53

bolts

54

gap

55

Cable gland

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102004008569 A1 [0008]
• EP 2945215 B1 [0010]

Cited non-patent literature

• ATEX Directive 2014/34 / EU [0002]
• ATEX Directive 2014/34 / EU [0085]

Claims (14)

Battery power supply ( 1 ) for an industrial truck used in a potentially explosive area ( 8th ), with one, a housing body ( 47 ) and a lid ( 4 ) housing ( 2 ), wherein the housing body ( 47 ) a recording room ( 48 ) for receiving a battery trough ( 3 ), which has an interior ( 20 ) with a traction battery ( 25 ), and the lid ( 4 ) with securing means ( 53 ) releasably on the housing body ( 47 ) and the battery tray ( 3 ) a battery tray lid ( 49 ) and a floor ( 26 ) with it from the ground ( 26 ) extending walls ( 17 . 18 ), characterized in that at least one wall ( 17 . 18 ) in a ground ( 26 ) adjacent area one the wall ( 17 . 18 ) to the interior ( 20 ) passing recess ( 19 ) having. Battery power supply ( 1 ) according to claim 1, characterized in that the floor ( 26 ) in a plan view has a rectangular configuration with longitudinal sides and transverse sides and the longitudinal sides have a longitudinal extent which is greater than the longitudinal extent of the transverse sides and the walls ( 17 . 18 ) for the formation of the interior ( 20 ) at an angle to the ground ( 26 ) extend away from this and arranged on the transverse sides walls ( 17 ) one in the region of the middle of the longitudinal extent of the respective wall ( 17 ) arranged passing recess ( 19 ) and arranged on the longitudinal sides walls ( 18 ) two interspersing recesses ( 19 ), which at opposite end portions ( 22 ) of the longitudinal sides of the respective wall ( 18 ) are arranged. Battery power supply ( 1 ) according to claim 1 or 2, characterized in that the recesses ( 19 ) than the respective wall ( 17 . 18 ) passing through rectangular wall openings ( 21 ) are formed. Battery power supply ( 1 ) according to one of the preceding claims, characterized in that the recesses ( 19 ) at the bottom end region of the interior ( 20 ) of the battery trough ( 3 ) are formed and have a total area, which in the context of a type examination of the housing ( 2 ) by a in the housing ( 2 test explosion resulting in a test explosion in a battery trough ( 3 ), which is smaller than one of the battery troughs ( 3 ) and / or the housing ( 2 ) opening explosion internal pressure. Battery power supply ( 1 ) according to one of the preceding claims, characterized in that the recesses ( 19 ) at the bottom end region of the interior ( 20 ) of the battery trough ( 3 ) above the ground ( 16 ) are arranged in an area where a superposition wave occurs, which is caused by a in the housing ( 2 ) caused explosion. Battery power supply ( 1 ) according to one of the preceding claims, characterized in that between one of the housing body ( 47 ) facing the lid surface ( 31 ) and a lid ( 4 ) facing surface of the housing body ( 47 ) a finely machined splitting surface ( 33 ) is formed with a predetermined gap surface width and a center roughness less than or equal to 6.3 microns. Battery power supply ( 1 ) According to one of the preceding claims, characterized in that the cover ( 4 ) on the housing body ( 47 ) by means of a plurality of screw connections ( 53 ) is releasably fixed and the screw connections ( 53 ) along an outer perimeter line ( 28 ) of the lid ( 4 ) are provided extending and are arranged at a predetermined distance from each other. Battery power supply ( 1 ) according to one of the preceding claims, characterized in that between the receiving space ( 48 ) and a bottom ( 35 ) of the battery tray lid ( 49 ) on the battery tray ( 3 ) releasably fixable intermediate cover ( 36 ) is provided, a receiving space ( 37 ) between a top side ( 38 ) of the intermediate cover ( 36 ) and the underside ( 35 ) of the battery tray lid ( 49 ) and for receiving an electronic circuit ( 14 ) is trained. Battery power supply ( 1 ) according to one of the preceding claims, characterized by cable glands ( 5 . 6 . 7 . 10 . 11 ) for providing an electrical charging connection for charging the traction battery ( 26 ) and an electrical power connection for providing electrical energy for the industrial truck ( 8th ). Battery power supply ( 1 ) according to one of the preceding claims, characterized by a contactor ( 43 ) switchable load circuit for the operation of the industrial truck ( 8th ) and one with a contactor ( 44 ) switchable charging circuit for charging the traction battery ( 25 ). Battery power supply ( 1 ) according to claim 10, characterized by an externally switchable and with the contactors ( 43 . 44 ) coupled connection device ( 45 ) such that the external circuit alternately switches the load circuit voltage-free and the charging circuit turns on in such a way that the load circuit is energized when the charging circuit is switched. Battery power supply ( 1 ) according to one of claims 8 to 11, characterized by an interface device ( 12 ) in the form, in particular, of a CAN bus interface device for exchanging data and / or signals between the one with the traction battery ( 25 ) functionally coupled electronic circuit ( 14 ) and an external charging device for charging the traction battery ( 25 ). Battery power supply ( 1 ) according to one of the preceding claims, characterized in that the traction battery ( 25 ) of a plurality of lithium iron phosphate cells ( 39 ) which is largely parallel to the ground ( 26 ) of the battery trough ( 3 ) and between the cells ( 39 ) White spaces ( 41 ) for the passage of gaseous fluid from the interior ( 20 ) to the recess ( 19 ) are provided. Industrial truck ( 1 ) with at least one electrically actuated drive device for driving the industrial truck ( 8th ) and / or moving a load, characterized by a battery power supply ( 1 ) according to any one of the preceding claims.

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