DE102017215242A1 - NTC component for installation in the electrical circuit of an electrical unit - Google Patents

Abstract

An NTC component for installation in the circuit of an electrical component has a housing and two connection elements, which are electrically connected via an intermediate NTC resistance element. Inside the housing, a compensation element is arranged, on which a connection element is supported. The two connection elements and the NTC resistance element are subjected to a force via a spring element against an inner wall of the housing.

Description

The invention relates to an NTC component (negative temperature coefficient) for installation in the circuit of an electrical unit, for example an electrical unit in a starting device for an internal combustion engine.

State of the art

In the DE 41 06 247 C1 a starter motor with a starter motor and a starter relay for transferring a starter pinion between a disengaged position and an engagement position with a ring gear of an internal combustion engine is described. After reaching the engaged position, the starter pinion is driven by the electric starter motor. For a temperature-independent function, the exciter winding of the starter relay is connected in series with a parallel circuit consisting of an NTC resistor (negative temperature coefficient) and an ohmic resistor. The NTC resistor conducts the electrical current better at high temperatures than at low temperatures and thereby limits the relay current, which is increased at low temperatures due to a positive temperature coefficient (PTC) behavior of the relay winding. The concomitant increased pull-in force, which acts on the starter pinion, can be compensated via the NTC resistance element.

Other starting devices with an NTC resistor element in the circuit of an electrical unit are from DE 41 22 252 A1 . DE 103 17 466 A1 . DE 10 2007 036 789 A1 and DE 2012 215 338 A1 known.

Disclosure of the invention

The NTC component (negative temperature coefficient) according to the invention can be used for installation in the circuit of an electrical unit, for example in the circuit of an electrical unit in a starting device, which is used to start internal combustion engines. Such a starting device has a starter pinion and an electromagnetic starter relay, which transfers the starter pinion between a disengaged position and an engagement position with a ring gear of the internal combustion engine. To drive the starter pinion in the engaged position is an electric starter motor. In the circuit of an electrical unit of the starting device - preferably the electric starter motor, optionally additionally or alternatively, the starter pinion - can be arranged NTC component that conducts the electric current better at high temperatures than at low temperatures. The NTC component limits in particular at the beginning of the starting phase, the short-circuit current, whereby a voltage drop in the electrical system of the vehicle is prevented or at least mitigated. Also, a higher electrical conductivity at low temperatures in the starter motor or in the starter relay can be partially or completely compensated by the NTC component and increased wear can be avoided.

The NTC component has a housing and two connection elements for the electrical connection to the circuit, wherein between the connection elements within the housing there is an NTC resistance element, through which the electric current flows and to which the connection elements are electrically connected. The connecting elements protrude advantageously out of the housing, wherein on the protruding portion of a connection element, the connection is made with an electrical connection cable or a strand of the circuit. It is also possible that one connection element or both connection elements do not protrude out of the housing and the connection to the circuit takes place by inserting a connection cable into the NTC component. The two connection elements and the intermediate NTC resistance element can form a coherent unit.

Within the housing is a compensating element on which a connection element is supported directly or indirectly. The two connection elements as well as the NTC resistance element arranged between the two connection elements are subjected to a force against an inner wall of the housing via a spring element, which is also preferably arranged inside the housing. The spring force of the spring element presses on a side surface of a first connection element and presses the first connection element against the NTC resistance element and this against the second connection element, whose opposite side surface is pressed against the nearest housing inner wall.

This design makes it possible to use connection elements of different shape and different thickness with unchanged outer geometry of the housing and to hold under a defined spring tension backlash in the housing. It is therefore possible to use various connection elements for a housing with an unchanged outer dimension, so that the installation space in the electrical component for the NTC component remains substantially unchanged, regardless of the connection elements used.

The adaptation to different geometries of the connection elements via the compensation element, which is arranged in the housing. Differently thick connection elements can over a appropriately compensated compensation element can be compensated. In particular, a different thickness of the compensating elements can be compensated with an adapted thickness of the compensating element. This also makes it possible to achieve a constant bias with unchanged spring element, with which the connection elements and the intermediate NTC resistance element are acted upon. It can thus continue to be used even with changed connection elements, the spring element. Alternatively, it is also possible to use another spring element when the geometry of the connection elements changes.

The compensating element mechanically compensates for a changing geometry of the connecting elements.

Within the housing, the various elements of the NTC component are protected against external influences. The housing serves as mechanical protection as well as protection against the ingress of moisture.

According to an advantageous embodiment, the compensation element forms an inner wall of the housing. A connection element bears in particular directly against a compensation element and is supported against the compensation element. But also comes an indirect support by between the compensation element and the connection element is still another component or a layer.

According to yet another expedient embodiment, the compensation element and the spring element are located on opposite inner sides of the housing. The spring element acts on a first connection element and presses the first connection element, the intermediate NTC resistance element and the second connection element against the oppositely arranged compensation element.

Alternatively, it is also possible to arrange the compensation element and the spring element on the same side in the housing. It is for example possible that the spring element between the compensation element and the nearest connection element is arranged.

According to yet another advantageous embodiment, the housing has a cover and the compensation element is arranged on the inside of the cover. The cover, together with a base housing, the housing and can be removed from the base housing and placed on this. The compensating element on the inside of the cover thus passes with the placement of the cover on the base housing in the support position for the nearest connection element in the NTC component. The compensation element is either formed integrally with the cover, with the replacement of the cover and arranged thereon compensation element adaptation to different geometries of the connection elements is possible. But also comes in a separate embodiment of the compensating element, so that the adaptation to different geometries of the connecting elements exclusively via different compensation elements and the lid can be maintained. In a separate embodiment of the cover and compensation element, it may be appropriate to attach the compensation element to the inside of the cover. In principle, it is also possible that the compensating element is used without attachment of the lid only in the housing and fixed with the placement of the lid.

There are various spring elements into consideration, which act on the connecting elements and the intermediate NTC resistance element with spring force. The spring element is formed for example as a leaf spring or corrugated spring, which is supported on a housing component and applied directly or indirectly, the connecting elements and the NTC resistance element with spring force. The support is in particular at the level of the NTC resistance element.

• 1 einen Schnitt längs durch eine Startvorrichtung für eine Brennkraftmaschine, wobei im Stromkreis eines elektrischen Startermotors ein NTC-Bauteil angeordnet ist,
• 2 einen Schnitt durch das NTC-Bauteil.

Further advantages and expedient embodiments can be taken from the further claims, the description of the figures and the drawings. Show it:

• 1 a section longitudinally through a starting device for an internal combustion engine, wherein in the circuit of an electric starter motor, an NTC component is arranged,
• 2 a section through the NTC component.

In the figures, the same components are provided with the same reference numerals.

The starting device 1 is used to start internal combustion engines and has in a shield forming a housing 2 an electric starter motor 3 on, a gearbox 4 , which is designed as a planetary gear, a drive shaft 5 , an overrunning clutch 6 as well as a starter pinion 7 to be adjusted axially between a retracted disengagement position and an advanced engagement position (shown in phantom) in which the starter pinion 7 in engagement with a sprocket 23 the internal combustion engine is stationary. The axial adjustment movement of the starter pinion 7 is using an electromagnetic starter relay 8th carried out on the bearing plate of the starting device 1 is held or flanged.

The starter motor 3 is in the embodiment as a permanent-magnet DC motor with permanent magnets on the inside of the motor or Polgehäuses 10 executed. The starter motor 3 has an anchor 11 with a rotating armature shaft 12 on, one on the armature shaft 12 seated anchor package 13 with currentable windings and a commutation device 30 with a collector 14 for power transmission and application to the windings of the anchor packet 13 ,

The planetary gear 4 is from the armature shaft 12 the starter motor 3 driven and has a housing fixed held ring gear 15 with internal toothing, planet gears 17 on a planet carrier 18 as well as a central sun wheel 19 on. The gear parts are in a gear housing component 16 added. The sun wheel 19 sits on the front side of the armature shaft 12 on and is non-rotatable with the armature shaft 12 connected. The sun wheel 19 meshes with the planet wheels 17 at the same time on the toothed inside of the ring gear 15 roll. The planet wheels 17 are rotatable on shafts on the planet carrier 18 mounted, the rotationally fixed to the drive shaft 5 connected on which the starter pinion 7 seated. In this way, the drive movement of the armature shaft 12 the starter motor 3 over the planetary gear 4 in a rotational movement of the drive shaft 5 implemented. The gear 4 has the function of a reduction gear.

The overrunning clutch 6 includes a driver 20 and sits on the drive shaft 5 on. The driver 20 is over a steep thread 21 with the drive shaft 5 coupled. To overrunning clutch 6 further includes a pinion shaft 22 , which are integral with the starter pinion 7 trained and with the driver 20 is rotationally coupled via rolling elements. The overrunning clutch 6 allows a torque transmission in the rotational or drive direction of the starter motor, whereas in the opposite direction no movement or torque transmission is possible. This ensures that after starting the internal combustion engine in a overhaul of the ring gear relative to the starter pinion damage to the starter motor is avoided.

The axial adjustment movement of the starter pinion 7 is activated by an actuation of the electromagnetic starter relay 8th generated, which has an axially adjustable lifting armature 24 which has a fork lever 25 with the driver 20 is coupled. When the starter relay is actuated 8th becomes the lifting anchor 24 axially adjusted, this adjusting movement is via the fork lever 25 in an axial deflection movement of driver 20 and starter pinion 7 implemented. Due to the coupling of the driver 20 over the coarse thread 21 with the drive shaft 5 leads in the axial feed movement, the overrunning clutch 6 including starter pinion 7 a rotational movement, which facilitates the meshing in the sprocket in a tooth-on-tooth position.

Once the starter pinion 7 has reached its axially advanced engagement position with the ring gear, the electric starter motor 3 started and the rotational movement of the armature shaft 12 on the starter pinion 7 transfer.

The starting device 1 is trained free ejecting. The drive shaft 5 is in the area of its free end face in the housing or end shield 2 taken in an open recess and there in a warehouse 26 rotatably mounted. Axially adjacent to the bearing 26 located on the inside of the bearing plate 2 a stop ring 27 on the drive shaft 5 that is axially fixed to the drive shaft 5 connected is. The drive shaft 5 has for this purpose a circumferential groove into which the stop ring 27 or a stop ring 27 supporting circlip is inserted.

The windings in the anchor package 13 be via the commutation device 30 energized. In the circuit in which the commutation device 30 is arranged, lies an electrical connection cable 28 that with an NTC component (Negative Temperature Coefficient) 29 electrically connected. The circuit of the commutation device 30 is from the electric starter relay 8th upon deflection of a lifting armature of the starter relay 8th closed. The NTC component 29 in the circuit of the commutation device 30 of the electric starter motor 3 conducts at high temperatures the electric current better than at low temperatures and thereby compensates for a reverse behavior of the electric starter motor, so that over a wider temperature range, a balanced behavior of the starter motor is achieved. The commutation device 30 includes the collector 14 , which rotates with the armature shaft 12 the starter motor 3 is connected, and in brush guides adjustably mounted brushes that are in the circuit.

If necessary, an NTC component can also be incorporated in the circuit of the starter relay 8th be integrated.

In 2 is a sectional view of the NTC component 29 shown. The NTC component 29 includes a housing 31 that is made up of a basic housing 35 and a lid 36 composed on the base housing 35 can be placed. The housing 31 is open to one side. In the case 31 are two electrical connection elements 32 and 33 taken over the open side of the case 31 protrude and over an intermediate NTC resistance element 34 are electrically connected. The NTC resistor element 34 is completely inside the case 31 of the NTC component 29 , The two connection elements 32 and 33 are used to connect to electrical connection cables and run parallel to each other. The NTC resistor element 34 is in the case 31 protected against external influences.

On the inside of the lid 36 there is a compensation element 37 , which is also designed as a housing component and with the lid 36 connected is. If necessary, lids 36 and compensation element 37 executed in one piece. There are also versions as separate components into consideration, which are fixed or possibly releasably connected together.

By adjusting the thickness d of the compensating element 37 can have different dimensions of the connection elements 32 and 33 and optionally the NTC resistor element 34 with unchanged dimensions of the housing 31 be compensated. It is therefore only necessary if the dimensions of the connection elements change 32 and 33 and optionally the NTC resistor element 34 an adjusted compensation element 37 to use, with unchanged outer dimensions of the housing 31 a play-free fit of the compensation elements 32 . 33 in the housing.

On the opposite side of the compensating element is supported on the inside of the base housing 35 a spring element 38 off, the two connecting elements 32 and 33 including the intermediate NTC resistance element 34 against the compensation element 37 acted upon with force. This support force on the package or assembly consisting of the two connecting elements 32 and 33 and the NTC resistor element 34 , works and directly on the compensation element 37 directed, can always be kept the same size even with different geometries of the connection elements and the NTC resistance element by only the compensation element 37 adapted to the current geometry. Regardless, it is also possible to use different spring elements to the contact pressure on the connecting elements 32 . 33 and the NTC resistance element 34 adapt.

In the embodiment, the spring element is located 38 in a recess formed in the inner wall of the basic housing 35 is introduced. The position of the spring element 38 is at the position of the NTC resistor element 34 aligned.

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 4106247 C1 [0002]
• DE 4122252 A1 [0003]
• DE 10317466 A1 [0003]
• DE 102007036789 A1 [0003]
• DE 2012215338 A1 [0003]

Claims (10)

NTC component (negative temperature coefficient) for installation in the circuit of an electrical unit, characterized in that the NTC component (29) has a housing (31) and two connecting elements (32, 33), which are connected via an NTC resistance element (34) are electrically connected, wherein inside the housing (31) a compensation element (37) is arranged, on which a connection element (32, 33) is supported, and that the two connection elements (32, 33) and the intermediate NTC resistance element (34) via a spring element (38) against an inner wall of the housing (31) are subjected to force. NTC component after Claim 1 , characterized in that the compensating element (37) forms an inner wall of the housing (31). NTC component after Claim 1 or 2 , characterized in that the compensating element (37) and the spring element (38) on opposite inner sides of the housing (31) are arranged. NTC component after one of Claims 1 to 3 , characterized in that the housing (31) has a cover (36) and the compensating element (37) is arranged on the inside of the cover. NTC component after Claim 4 , characterized in that the compensating element (37) and the lid (36) are integrally formed. NTC component after one of Claims 1 to 5 , characterized in that the compensating element (37) flat against the side surface of a connecting element (32, 33). NTC component after one of Claims 1 to 8th , characterized in that the two connection elements (32, 33) protrude from the housing (31). Starting device for an internal combustion engine, comprising a starter pinion (7) and a starter relay (8) for transferring the starter pinion (7) between a disengaged position and an engaged position in which the starter pinion (7) is engaged with a ring gear (23) of the internal combustion engine, with an electric starter motor (3) for driving the starter pinion (7) and with an NTC component (29) according to one of Claims 1 to 7 in the circuit of an electrical unit of the starting device (1). Starting device after Claim 8 , characterized in that the NTC component (29) in the circuit of the starter motor (3) of the starting device (1) is arranged. Starting device after Claim 8 or 9 , characterized in that the NTC component (29) in the circuit of the starter relay (8) of the starting device (1) is arranged.

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