DE102016209617A1 - Electric drive unit with a housing - Google Patents

Abstract

The invention relates to an electric drive unit (10), in particular for adjusting moving parts in the motor vehicle, having a housing (11), comprising a pole housing (12) which accommodates a trunk motor (18) having a rotor axis (20), and an axially adjoining electronics housing (30), which accommodates an electronics unit (89), wherein the electronics housing (30) has a first axial housing part (31) whose axially open - from the pole housing (12) facing away - (40) from a second axial housing part (32) is closed, wherein both the pole housing (12) and the first and the second axial housing part (31, 32) of the electronics housing (30) are formed of metal.

Description

State of the art

The invention relates to an electric drive unit with a pole housing and an electronics housing according to the preamble of the independent claim.

From the DE 10 2012 222 683 A1 An electric machine has become known which has a pole pot made of metal. On the pole pot, a plug component made of plastic is arranged axially, on which in turn a cover made of electrically conductive material is arranged. The lid is clamped to the pole pot by a plurality of steel spring clips, so that the three components are fixed against each other. If the housing is to be sealed watertight, in such an embodiment, in each case a sealing element between the different components is necessary. The connection technique of such a sandwich arrangement (metal-plastic-metal) is relatively complex and in particular at an extreme shaking load such compounds can be solved, whereby the housing can be leaking.

Disclosure of the invention

The electric drive unit according to the invention comprises a housing in which three axially adjoining housing parts are formed from metal. In this case, a pole housing, in which the stator and the rotor of an electric motor is arranged, directly connected to an electronics housing, which is completely formed with metal walls except for a connector outlet. In order to mount the electronics more easily in the electronics housing, the electronics housing is formed in two parts, wherein a first housing part connects with an axially open side to a second, also axially open housing part. After connecting the three metal-made housing elements, the electric drive unit is practically completely enclosed by a metal cage, on the one hand forms a very good electromagnetic shielding, and on the other hand excellent heat that is generated within the housing, can dissipate to the environment. In addition, such a metal housing is mechanically very stable, so that the electric drive unit can be exposed to large shocks, without the housing is leaking.

The measures listed in the dependent claims, advantageous refinements and improvements of the main claim features. A particularly high stability is achieved when the connection between the individual housing elements are formed cohesively. Preferably, the housing elements are welded or soldered together, wherein the connecting seam can be very easily formed completely sealed without interruption. Manufacturing technology, it is particularly advantageous to perform both connection processes with the same procedure. Thus, the housing is extremely stable and tight when both the pole housing with the first housing part of the electronics housing, and the first housing part with the second housing part of the electronics housing are welded or soldered together.

In this case, at least one of the two axial housing parts of the electronics housing can be manufactured very cost-effectively from sheet steel. Such a steel sheet can process favorable formed by deep drawing or stamping. If a stainless steel is used, or if the steel sheet is galvanized, the housing can be effectively protected against corrosion.

Preferably, at least one of the two axial housing parts made of aluminum, in order to ensure a particularly good heat dissipation. Such an aluminum housing part can be very easily manufactured by means of die-casting or injection molding, wherein simultaneously cooling elements with a large surface area can be formed. In a preferred embodiment, the second, the pole housing remote electronics housing part is formed of aluminum. The first housing part, which is arranged between the pole housing and the second electronics housing part, is preferably produced as a trough-shaped deep-drawn part of sheet steel.

If the two housing parts are in principle shell-shaped, a flange can be formed on their open edge, on which the two housing parts can be connected to one another. Both housing parts may have a flange or only one. Due to the shell-shaped design of the housing parts, these have a peripheral to the rotor axis circumferential wall whose axial extent can be selected according to the required volume for the electronics unit accordingly. If the two housing parts welded or soldered together, on the one hand two directly axially abutting flanges can be firmly bonded together. Alternatively, an axially extending peripheral wall of the one housing part can be placed on the flange of the other housing part and connected to each other by means of a circumferential weld or solder seam.

Due to the formation of a parting plane in the electronics housing transversely to the rotor axis can be very conveniently inserted a larger circuit board in the first or second housing part, and then the two housing parts are sealed tightly together. If the circuit board is also arranged in a plane transverse to the rotor axis, this can be made very large for receiving many electronic components, so that the circuit board can also be made larger than the cross section of the pole housing. As a result, there is enough space on the printed circuit board for power electronics, for controlling an EC motor or for arranging a rotary position sensor.

Preferably, the printed circuit board is applied with its heat-generating electronic components in thermal contact directly to the inner wall of the first or second housing part. In a particularly simple manner, the printed circuit board can be glued to the housing part, wherein also thermally conductive adhesive can be used. For example, if the second, the pole housing modified housing part, formed of aluminum, this represents a particularly good heat sink, so that the circuit board is attached directly to the aluminum housing part.

For electrically contacting the drive unit, a hole is formed in the housing wall in the region of the electronics housing in the first or second axial housing part, through which electrical leads are led from the electronics unit inside the housing to the outside by means of an electrical connection plug. The connection plug has a plug collar outside the housing, within which the connection pins are arranged. The terminal plug can either be inserted from outside the housing through the hole in the housing to the inside, or in an alternative embodiment of the connector plug are also guided from within the housing through the hole to the outside. Between the housing wall and the connection plug can advantageously be inserted an elastic sealing element which is pressed in the attachment of the connection plug between the housing wall and the connection plug.

Preferably, the plug connection in the first, the Poltopf facing housing part, in particular at the radial peripheral wall, inserted. As a result, after the first housing part has been mounted on the pole pot, the connection plug can be completely assembled through the axial opening of the first housing part. Thereafter, the second housing part, in which, for example, the circuit board is attached, are axially joined to the first housing part. In an alternative embodiment of the drive unit, the connection plug can also be inserted at an axial bottom surface of the first housing part or on a corresponding surface of the second housing part in a corresponding passage.

In order to prevent heat conduction or heat radiation between the electronics unit in the electronics housing and the electric motor in the pole housing, a thermal insulation shield can be arranged within the electronics housing. Such an insulation shield can be produced in a particularly favorable manner from a poorly heat-conducting plastic. The insulation shield preferably extends approximately parallel to the circuit board, so that it is thermally shielded over a large part of its surface relative to the electric motor.

The insulation shield can be fastened directly in one of the two housing parts or on the printed circuit board or on the connection plug.

Due to the formation of the two housing parts made of metal, these metal fasteners can be welded or soldered in these very simple. These fasteners may be formed, for example, as threaded sleeves, threaded pins or bolts, by means of which the two housing parts can be connected together. Likewise, the electronic unit and / or the insulation shield attached - in particular screwed - to these fasteners.

The arrangement of the electronic unit axially directly above the electric motor, a signal generator can be advantageously arranged at one end of the rotor shaft, which cooperates with a corresponding sensor of the electronic unit. In this way, the rotor position can be detected by the electronic unit, for example to control the electronic commutation of the electric motor or to determine the rotational speed of the rotor shaft or the position of a driven by the rotor shaft part. On the open side of the pole pot, a bearing plate is preferably arranged, in which the rotor shaft is supported for example by means of a ball bearing. In this case, the rotor shaft passes through the bearing plate and projects into the electronics housing, wherein the signal generator is preferably arranged at the free end of the rotor shaft.

Thus, the signal transmitter of the rotor shaft passes in the immediate vicinity of the electronic unit, a corresponding recess is formed in the insulation shield, through which passes through the rotor shaft with the signal transmitter axially. It is particularly advantageous if the signal transmitter emits signals in the axial direction, which can detect an axially directly opposite sensor element. It is particularly advantageous if the sensor element is arranged directly on the circuit board, this for example, can detect the orientation of a magnetic field.

Due to the separate installation of the connection plug suppression components can be arranged particularly favorable at this. For particularly large suppression components, the first housing part may also have an axial write-off to the electric motor to provide sufficient space for the suppression components available. If the insulation shield is located, for example, on the connection plug, the suppression component can also be mounted directly on the insulation shield.

Due to the arrangement of the electronics housing on the axially open side of the pole pot, a passage opening in the bottom of the pole pot can be formed on the opposite side of the pole pot, through which the rotor shaft protrudes to the outside. As a result, at the second free axial end of the rotor shaft, an output element can be formed or arranged, which for example displaces a movable part in the motor vehicle or drives a pump or blower. Due to the metal bottom surface of the pole pot and the metal peripheral wall, which simultaneously forms the magnetic return path, the drive unit together with the metal electronics housing is practically completely enclosed by a Faraday cage. As a result, electromagnetic interference radiation can neither escape from the drive unit nor penetrate into it.

Description of the drawings

Further features of the invention will become apparent from the further embodiments of the description and the drawing, as described in the following embodiment of the invention. It shows:

1 an embodiment of an electric drive unit according to the invention.

In 1 is an electric drive unit 10 shown as an electric motor 9 with a housing 11 is trained. In a pole housing 12 of the housing 11 is a stator 60 arranged with one on a rotor axis 20 arranged rotor 62 interacts. The rotor 62 has a rotor shaft 64 on, on which a rotor body 66 is arranged, which preferably consists of individual laminations 67 is composed. The rotor shaft 64 is in the embodiment by means of a first bearing 68 on the ground 14 of the pole housing 12 stored. For this purpose, the pole housing 12 an axial extension 16 acting as a bearing seat for the first camp 68 is trained. The pole housing 12 is as a pole pot 13 formed, which is made for example as a deep-drawn part. The rotor shaft 64 protrudes with a second axial end 63 through a breakthrough 70 of the pole housing 12 out of this, to a torque of the electric motor 9 to transfer to a not-shown gear or pump or blower. This is the breakthrough 70 on the axial extension 16 formed, wherein outside the pole housing 12 on the rotor shaft 64 an output element 74 arranged, or on the rotor shaft 64 is formed. The pole housing 12 is made of metal and is thus as a magnetic conclusion for the stator 60 educated. In the training of the electric motor 9 as EC engine 8th are in the stator 60 in the radial outer region of the pole housing 12 electric coils 76 arranged to generate a magnetic field in the rotor 62 arranged permanent magnets 78 to turn. The pole housing 12 is in this embodiment as an approximately cylindrical pole pot 13 formed, which is axially open. At the axial opening 80 of the pole housing 12 is a bearing shield 50 arranged in which a second camp 58 the rotor shaft 64 is attached. The bearing plate 50 is made, for example, of metal as a stamped and bent part and on the open edge 81 of the pole housing 12 welded. Through the second camp 58 protrudes through, the output element 74 opposite first free end 65 the rotor shaft 64 on which a signal generator 83 is arranged for rotor position detection. Between the end shield 50 and the coils 76 is a wiring plate 77 arranged the individual coils 76 interconnects and electrical phase connections 75 axially through the bearing plate 50 through from the inside of the pole housing 12 in the electronics housing 30 leads. The pole housing 12 with the rotor completely supported therein 62 represents a preassembled unit of a fuselage engine 18 is, can be flanged to the axially different housing components. This is at the open edge 81 of the pole housing 12 a flange 22 molded, at the axially in the embodiment, an electronics housing 30 is applied, consisting of a first axial housing part 31 and a second axial housing part 32 is composed. The pole housing 12 and the electronics housing 30 together form the housing 11 the drive unit 10 ,

The first axial housing part 31 lies axially on the pole housing 12 at. For this purpose, the first axial housing part 31 a counterflange 23 on, the preferred with the flange 22 of the pole housing 12 is welded. The flange 22 and the counterflange 23 are approximately circular, wherein the base of the first axial housing part 31 in the plan view in 1 is formed from above approximately rectangular, for example, and the pole housing 12 protrudes radially. The first axial housing part 31 points at the axially from the pole housing 12 facing away from a mounting hole 40 on, that of the second axial housing part 32 is completely closed. That means that electronics housing 30 a dividing plane 34 transverse to the rotor axis 20 comprising, on which the two axial housing parts 31 . 32 connected to each other. According to the execution in 1 has for this purpose the first axial housing part 31 axially opposite to the counterflange 23 a second flange 35 on, on a second flange 36 of the second housing part 32 is trained. Also this second flange 35 lies on the second flange 36 and is preferably by means of a completely around the rotor axis 20 extensive weld with the second flange 35 connected. The mounting hole 40 in the parting plane 34 is approximately rectangular. The second flange 35 and the counterflange 36 enclose the mounting hole 40 and are therefore also approximately a rectangular shape. The first housing part 31 is here designed as a deep-drawn part of sheet metal. For example, this is a stainless steel sheet or a galvanized sheet steel used to a Korrision of the electronics housing 30 to avoid. The second housing part 32 is, however, made of aluminum for better heat dissipation. For example, this aluminum housing part is produced by means of injection molding or die casting. In this case, on the outer wall of the second housing part 32 heat-conducting elements 38 molded, for example, as cooling fins 39 or cooling knobs are formed.

For mounting the electric drive unit 10 First, the hull engine 18 with the first axial housing part 31 connected, preferably welded to this. In this state, the first housing part 31 over the mounting hole 40 be fitted axially with other components. Likewise, the second housing part 32 before this on the first housing part 31 is fitted with appropriate components. In the embodiment, the first housing part 31 a connection plug 42 for electrical contacting of the drive unit 10 arranged. For this purpose is on a radial peripheral wall 43 of the first housing part 31 a passage opening 44 formed, in which the connection plug 42 is inserted. The connection plug 42 has a plug collar 45 on, in which the individual pins 46 are arranged for the power supply and the sensor signals. The connection plug 42 is here radially from the outside in the breakthrough 44 plugged in, and on the inside of the radial peripheral wall 43 attached, for example screwed, clipped or riveted. Between the connection plug 42 and the wall of the first housing part 31 becomes a sealing element 47 pressed. The sealing element 47 is here for example as a cuff seal 48 formed with the connector plug 42 in the breakthrough 44 is inserted radially from the outside with. Inside the electronics housing 30 is on the connection plug 42 a first suppression element 52 arranged, for example as a suppression capacitor 53 is trained. The suppression element 52 Can be before or after mounting the connection plug 42 be connected with this. To have enough space inside the electronics housing 30 To provide, has the first housing part 31 in the area of the suppression element 52 an axial bulge 55 into, into which the first interference suppression element 52 extends. Parallel to the parting line 34 is in the electronics housing 30 an isolation shield 86 arranged, which is the trunk motor 18 thermally opposite a printed circuit board 88 isolated, which is part of the electronics unit 89 is. In the embodiment, the insulation shield 86 at the connection plug 42 attached. In an alternative embodiment, the insulation shield 86 also directly on the electronics housing 30 or the circuit board 88 be attached. The isolation shield 86 has a recess 87 on, through which the first free end 65 the rotor shaft 64 with the signal transmitter 83 protrudes axially. In the embodiment is on the insulation shield 86 a second suppression element 54 arranged, for example, also as a suppression capacitor 53 is formed, wherein optionally only the first suppression element 52 or the second suppression element 54 is installed. Before the second axial housing part 32 axially on the mounting hole 40 of the first housing part 31 is attached, the circuit board 88 on the inside of the second housing part 32 taped. These are electronic components 90 , which tend to produce a lot of heat, applied directly to the inner wall. In this case, for example, a good thermal conductivity adhesive can be used. The circuit board is preferred 88 electrically insulating in the second housing part 32 inserted, but optionally can also directly a ground contact of the circuit board 88 to the electronics housing 30 getting produced. As an alternative to gluing, the circuit board 88 also hard or soft in the electronics housing 30 screwed or clipped. To protect against shocks, the circuit board 88 also be stored floating or by means of spring elements damping. In the embodiment are in the electronics housing 30 schematically fastening pin 92 arranged on which the circuit board 88 and / or the insulation shield 86 are attached. Alternatively, the two housing parts 31 . 32 be screwed together by means of threaded bolts designed as fixing pins. On the circuit board 88 is on the the hull engine 18 facing side, a sensor element 94 arranged, which signals the signaler 83 can evaluate. For example, the signal generator 83 as a sensor magnet 84 formed, the axial magnetic field of a magnetic sensor 95 trained sensor element 94 is detectable. This can be designed, for example, as a GMR or GMX sensor, which directly determines the rotational position of the sensor magnet 84 can capture. The electronics unit 89 can evaluate this signal to hereby, for example, the electronic commutation of the EC motor 8th head for. In addition, the Drehlagesignal also for the Movement of the output element 74 be used for different applications. When mounting the second housing part 32 with the circuit board 88 becomes an electrical connection between the phase terminals 75 and the pins 46 with the circuit board 88 produced. This can be produced for example by means of plug connections. In an alternative embodiment, the circuit board 88 also before closing with the second housing part 32 axially in the first housing part 31 inserted and / or fixed. In this case, the shape of the first and the second housing part 31 . 32 vary. In particular, the axial height of the radial peripheral wall 43 both of the first housing part 31 as well as the second housing part 32 be varied accordingly, causing the dividing plane 34 corresponding axially from the fuselage engine 18 moving away or away. For example, the first or the second housing part 31 . 32 only as a plate without radial peripheral wall 43 be formed, in which case the corresponding other housing part 32 . 31 a correspondingly axially higher radial peripheral wall 43 having. Instead of the cohesive connection between the pole housing 12 and the first housing part 31 , as well as between the two housing parts 31 and 32 For example, other bonding techniques such as crimping, clinching, toxicity or screwing may also be used. Depending on the application, this may also be possible to dispense with a seal.

In another embodiment, not shown, the connection plug 42 not directed radially outwards, but it is on a bottom surface 96 of the first housing part 31 the breakthrough 44 formed, through which the connection plug 42 extends axially downwards. Alternatively, the breakthrough 44 also in a lid area 98 of the second housing part 32 be formed, through which the connection plug 42 extends axially upwards.

It should be noted that in terms of in the 1 and the description shown embodiments diverse combination options of the individual features are possible with each other. Thus, the invention relates to the axial connection of three metal housing parts 12 . 31 . 32 an electric drive unit 10 , wherein the drive unit 10 In addition, may also comprise other housing components made of plastic, such as the connection plug 42 , Also, the execution of the second flange 35 and the second mating flange 36 the two housing parts 31 . 32 deviate from a rectangular shape, and for example also like the pole housing 12 be formed round or oval. Depending on the version of the drive unit 10 can the electronics housing 30 different electronic functional groups, such as the sensors 94 . 83 , the suppression elements 52 . 54 and the EC motor drive 90 record, always at least the electrical contact of the coils 76 must be realized. The innovative drive unit 10 is particularly suitable as an EC motor version 8th for adjusting movable components in the motor vehicle. In this case, such an inventive electric motor 9 with complete metal housing 11 particularly favorable for outdoor use, such as in the engine compartment, where it is exposed to extreme weather conditions and shocks.

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 102012222683 A1 [0002]

Claims (15)

Electric drive unit ( 10 ), in particular for adjusting moving parts in the motor vehicle, with a housing ( 11 ), comprising a pole housing ( 12 ), which has a rotor axis ( 20 ) having a trunk motor ( 18 ), and an axially adjoining electronics housing ( 30 ), which is an electronics unit ( 89 ), wherein the electronics housing ( 30 ) a first axial housing part ( 31 ), whose axially open - from the pole housing ( 12 ) away - page ( 40 ) of a second axial housing part ( 32 ), characterized in that both the pole housing ( 12 ) as well as the first and the second axial housing part ( 31 . 32 ) of the electronics housing ( 30 ) are formed of metal. Electric drive unit ( 10 ) according to claim 1, characterized in that the pole housing ( 12 ) with the first axial housing part ( 31 ) and / or the two axial housing parts ( 31 . 32 ) water-tight cohesively connected to each other - in particular welded or soldered over the entire circumference - are. Electric drive unit ( 10 ) according to claim 1 or 2, characterized in that the first or the second axial housing part ( 31 . 32 ) of a korossionsfesten steel - in particular as a deep drawn - is formed. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that the second or the first axial housing part ( 32 . 31 ) made of aluminum - in particular as an injection-molded part with molded-on heat-conducting elements ( 38 . 39 ) - is trained. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that the second or the first axial housing part ( 32 . 31 ) a radial peripheral wall ( 43 ), which extend in the axial direction ( 25 ), and thus the electronics housing ( 30 ) cup-shaped with a parting plane ( 34 ) transverse to the rotor axis ( 20 ) is formed - wherein in particular in the region of the parting plane ( 34 ) on the peripheral wall ( 43 ) of the first and / or the second axial housing part ( 31 . 32 ) a flange ( 35 ) and a counterflange ( 36 ) for connecting the two axial housing parts ( 31 . 32 ) is trained. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that the electronic unit ( 89 ) a printed circuit board ( 88 ), which in a plane transverse to the rotor axis ( 20 ) - and in particular radially over the circumference of the pole housing ( 12 ) extends. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that the electronic unit ( 89 ) in the first or in the second axial housing part ( 31 . 32 ) - preferably heat-conducting to an axial bottom or top wall ( 96 . 98 ) of the first or the second axial housing part ( 31 . 32 ) is glued. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that on the first or on the second axial housing part ( 31 . 32 ) a passage opening ( 44 ), in which an electrical connection plug ( 42 ) is inserted from plastic, wherein the plug pins ( 46 ) with the electronics unit ( 89 ), and the electrical connection plug ( 42 ) from the outside or from the inside of the electronics housing ( 30 ) in the breakthrough ( 44 ) - in particular a sealing element ( 47 ), preferably a boot seal ( 48 ), between the connection plug ( 42 ) and the breakthrough opening ( 44 ) enclosing housing wall is pressed. Electric drive unit ( 10 ) According to one of the preceding claims, characterized in that the opening ( 44 ) on the radial peripheral wall ( 43 ) or on the axial bottom or top wall ( 96 . 98 ) of the first or the second axial housing part ( 31 . 32 ) is arranged. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that axially between the electronic unit ( 89 ) and the fuselage engine ( 18 ) an insulation shield ( 86 ) - in particular of plastic - which covers the electronics unit ( 89 ) thermally opposite electrical coils ( 76 ) of the fuselage engine ( 18 ) shields. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that in the electronics housing ( 30 ) Fixing pins ( 92 ) - in particular welded - are, on which the electronic unit ( 89 ) and / or the insulation shield ( 86 ) and / or the connection plug ( 42 ) in the electronics housing ( 30 ) are fixed. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that in the pole housing ( 12 ) the electric coils ( 76 ) for driving a rotor ( 62 ) are arranged on a rotor shaft ( 64 ) along the rotor axis ( 20 ) and at one axial end ( 65 ) of the rotor shaft ( 64 ) a signal generator ( 83 ) arranged with a rotary position sensor system ( 94 ) of the electronics unit ( 89 ) cooperates, wherein the axial end ( 65 ) of the rotor shaft ( 64 ) by a bearing plate ( 50 ) for the rotor ( 64 ) axially into the electronics housing ( 30 protrudes. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that the signal transmitter ( 83 ) axially through a corresponding recess ( 87 ) in the insulation shield ( 86 ) protrudes through - and the signal generator ( 83 ) preferably a sensor magnet ( 84 ), whose axial magnetic surface with an axially oppositely arranged magnetic sensor ( 95 ) of the rotary position sensor system ( 94 ) cooperates. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that on the connection plug ( 42 ) and / or on the insulation shield ( 86 ) at least one suppressor component ( 52 . 54 ) - in particular a suppression capacitor ( 53 ) - is attached, wherein preferably at the first axial housing part ( 31 ) an axial bulge ( 55 ) for receiving the connection plug ( 42 ) and / or the suppressor component ( 52 . 54 ) is trained. Electric drive unit ( 10 ) according to one of the preceding claims, characterized in that on the the electronics housing ( 30 ) facing away from the pole housing ( 12 ) a passage opening ( 70 ) is formed, through which an output element ( 74 ) having second end ( 63 ) of the rotor shaft ( 64 ) from the pole housing ( 12 ), wherein in particular the pole housing ( 12 ) and the first and the second axial housing part ( 31 . 32 ) are electrically connected to each other over their entire circumference and also in the axial direction ( 25 ) form a closed Faraday cage against electromagnetic interference.

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