This application claims priority of German patent application no. 10 2013 009 669.3, filed Jun. 8, 2013, the entire content of which is incorporated herein by reference.
U.S. Pat. No. 7,261,280 B2 has disclosed a carburetor, in which, during normal operation, the fuel quantity which is to be fed to the feed channel is controlled via a fuel opening, the flow cross section of which is controlled using a slotted guide. The carburetor has a starting lever, by way of which a cold start position and a warm start position can be set. In the start positions, the throttle element is moved in the axial direction and rotated with respect to the non-actuated position, which results in an enlarged flow cross section and an increased fuel quantity which is fed in in comparison with the non-actuated position. The start positions are defined by way of latching positions of the starting lever. In order to release the latching action, the operator has to apply the throttle. A latching element slides off a cam contour during the application of the throttle. During the opening movement of the throttle element, the latching action is released. In the completely open position of the throttle element, the position of the throttle element is set using the slotted guide which is active during operation.
If the operator applies full throttle after starting, the start position is left quickly and the mixture which is fed to the internal combustion engine can be made lean to a pronounced effect, which leads to unfavorable running performance of the internal combustion engine.
It is an object of the invention to provide an internal combustion engine with a starter device of the kind referred to above. The internal combustion engine has favorable operating performance during starting and immediately after starting.
The internal combustion engine of the invention includes: an operator-controlled element; a supply channel for supplying combustion air for the engine; a throttle element mounted in the supply channel; the operator-controlled element being operatively connected to the throttle element to adjust the position thereof; a starter device having an operating position and a starting position; the starter device being configured to enable a defined clear flow cross section in the supply channel in the starting position; the starter device including an actuation unit for setting the starter device in the starting position thereof; a latching unit for latching the starter device in the starting position; the operator-controlled element being operatively connected to the latching unit for unlatching the latching unit in response to an actuation of the operator-controlled element; a fuel port having a free flow cross section and opening into the supply channel; a first ramp configured to control the free flow cross section of the fuel port in dependence upon the position of the throttle element when the starter device is in the operating position; a second ramp configured to control the free flow cross section of the fuel port in response to a first actuation of the operator-controlled element after the unlatching of the latching unit at least up to a closing operation of the throttle element following the first actuation of the operator-controlled element; and, the free flow cross section of the fuel port based on the second ramp being greater than a flow cross section adjusted for the same position of the throttle element based on the first ramp.
After starting of the internal combustion engine, the starting position of the starter device is released by way of actuation of an operator-controlled element, in particular by the application of throttle. As a result, the starter device is adjusted into its operating position. Here, the free flow cross section of the supply channel is enlarged and the fuel quantity which is fed in is reduced. In order to avoid the mixture being made excessively lean and therefore in order to avoid unfavorable operating behavior or stalling of the engine during the actuation of the operator-controlled element which immediately follows starting, that is, during actuation of the operator-controlled element, by way of which the latching action of the starter device is released, it is provided that the free flow cross section of the fuel port is controlled by a second ramp during the first actuation of the operator-controlled element after the release of the latching action. Here, the free flow cross section of the fuel port or opening which is set using the second ramp is greater than a flow cross section which is set for the same position of the throttle element using the first ramp. Here, the second ramp remains active at least until a closing operation of the throttle element which follows the first actuation of the operator-controlled element. If the operator quickly applies full throttle after starting of the internal combustion engine, the fuel quantity which is fed in is not set using the first ramp for operation, but rather using the second ramp for the starting operation. As a result, it can be avoided that the mixture is made excessively lean immediately after starting of the internal combustion engine.
The operating position of the starter device is advantageously a position, in which the starter device does not change or influence the free flow cross section in the feed channel. In the operating position of the starter device, the free flow cross section can be set by the operator by way of adjustment of the throttle element via the operator-controlled element. Here, the free flow cross section can be set between a minimum and a maximum free flow cross section. Here, the maximum free flow cross section can also be predefined structurally by the starter device or elements of the starter device, for example can be reduced in comparison with the maximum free flow cross section of an internal combustion engine without a starter device. However, the free flow cross section which is set is not influenced by the starter device in the structurally predefined limits, but rather is set by the throttle element.
The internal combustion engine advantageously has a guide element which interacts with the second ramp during the first actuation of the operator-controlled element after the release of the latching action. In order to deactivate the intermediate stop, it is provided that the guide element moves out of the second ramp during the closing of the throttle element which follows the first actuation of the operator-controlled element.
It is advantageously provided that the actuation unit moves at most partially in the direction of the operating position during the release of the latching action. Accordingly, the actuation unit can move partially in the direction of the operating position or can remain at a standstill in the position which is assigned to the starting position. In the starting position, the starter device advantageously holds the throttle element in a partially open position. As a result, it can be achieved in a simple way that the mixture is made richer for the starting operation. After the release of the latching action, the throttle element is advantageously reset into the operating position independently of the movement of the actuation unit.
The starter device can advantageously be adjusted from the operating position into the starting position by way of rotation of the actuation unit about an actuating axis and displacement of the actuation unit in the direction of the actuating axis. This results in simple actuation. At the same time, an unintended actuation of the starter device is avoided on account of the two independent actuating movements. Here, it can be provided both that the actuation unit is first to be rotated and subsequently to be adjusted in the direction of the actuating axis, and that the actuation unit is first to be adjusted in the direction of the actuating axis and is then to be rotated. The sequence of the two operating steps is advantageously predefined structurally.
The internal combustion engine advantageously has at least one further ramp. During the closing operation which follows the first actuation of the operator-controlled element, the guide element advantageously moves out of the second ramp into the further ramp. Here, the flow cross section of the fuel opening which is set using the further ramp is greater than a flow cross section which is set for the same position of the throttle element using the first ramp and is smaller than a flow cross section which is set for the same position of the throttle element using the second ramp. As a result, it is also achieved during the second actuation of the operator-controlled element which follows the first closing operation that the mixture which is fed to the internal combustion engine is made richer. A plurality of further ramps can also be advantageous. The fuel quantity which is fed in can be set over a plurality of actuating operations of the operator-controlled element after starting by way of two or more ramps. Here, the ramps are arranged so as to follow one another in a cascade-like manner, to be precise in such a way that, during each closing movement of the throttle element, the active ramp is deactivated and a following ramp is activated. Here, the number of ramps which are connected one after another is advantageously also adapted to the intended use of the internal combustion engine.
The starter device advantageously holds the throttle element in the starting position in a partially open position. As a result, a sufficient supply of combustion air can be ensured during starting.
A setting or adjustment needle which controls the fuel quantity which is fed in advantageously protrudes into the fuel opening. The starter device advantageously acts on the position of the setting needle and, in the starting position, enlarges the free flow cross section in the fuel opening. Here, the throttle element is, in particular, a control drum which is mounted such that it can be rotated about a pivot axis. Accordingly, the carburetor is a drum-type carburetor. The adjustment needle is advantageously held on the control drum, and the actuation unit of the starter device moves the control drum in the longitudinal direction of its pivot axis. In order to control the fuel quantity which is fed to the supply channel, an electrically actuated valve, in particular an electromagnetic valve, can be provided. The carburetor can be a diaphragm carburetor, in which the fuel quantity which is fed into the intake duct depends on the pressure in a control chamber which is loaded with a reference pressure.
The internal combustion engine advantageously has an intermediate stop. The intermediate stop is advantageously active during the first actuation of the operator-controlled element after the release of the latching action and prevents complete opening of the throttle element. During the following closing movement of the throttle element, the intermediate stop is advantageously deactivated, with the result that the throttle element can be opened completely during a following opening movement. As a result, it can be avoided after the starting operation in a targeted manner that the mixture is made excessively lean if the operator applies full throttle immediately after the starting operation, that is, actuates the operator-controlled element as far as a stop. The internal combustion engine can be adapted to run in a comparatively lean manner by virtue of the fact that the intermediate stop is deactivated during normal operation, and low exhaust gas values can be achieved. Here, the intermediate stop can be deactivated at any desired time during the closing movement of the throttle element until the completely closed position of the throttle element is reached. The intermediate stop is particularly advantageously deactivated toward the end of the closing movement, in particular immediately before the completely closed position of the throttle element is reached.
The intermediate stop can be an intermediate stop which is to be activated and deactivated mechanically. However, it can also be provided to actuate the intermediate stop electrically, for example via a corresponding actuator. A different type of activation of the intermediate stop, for example hydraulic or pneumatic, can also be advantageous.
The intermediate stop is advantageously formed on the second ramp. The intermediate stop is advantageously formed by way of a first stop element which is connected to the actuation unit and interacts with a second stop element which is connected to the throttle element. This results in a simple construction. If further ramps are provided, each further ramp can be assigned a further intermediate stop.
The internal combustion engine advantageously has a first supply duct for feeding in combustion air and a second supply duct for feeding in combustion air and fuel. In particular, the internal combustion engine is a two-stroke engine which operates with a scavenging gas shield. The throttle element advantageously controls the first supply duct and the second supply duct. Here, in the carburetor, the supply channel is advantageously divided at least partially into the first and the second supply ducts. However, it can also be provided that the first and the second supply ducts are configured as separate, completely separate ducts, that the throttle element controls the second supply duct, and that an additional throttle element is arranged in the first supply duct. The position of the additional throttle element is coupled, in particular, to the position of the throttle element in the second supply duct.
The invention will now be described with reference to the drawings wherein:
To guide the brushcutter 37 during operation, a guide arm 45, which supports two handles 41, is fixed on the guide tube 39. An operator-controlled element 42 is arranged on one of the handles 41. The operator-controlled element 42 is mounted pivotably on the handle 41 and is configured as a hand throttle. The operator-controlled element 42 serves to control the combustion air quantity which is fed to the internal combustion engine 1.
The internal combustion engine 1 has a cylinder 2 in which a combustion chamber 3 is formed. The combustion chamber 3 is delimited by a piston 5 which is mounted so as to move to and fro in the cylinder 2. Via a connecting rod 6, the piston 5 drives a crankshaft 7 rotationally which is mounted rotatably in a crankcase 4. In the region of the bottom dead center (shown in
For feeding in combustion air, the internal combustion engine 1 has an intake channel 26 which draws in combustion air via an air filter 17. The intake channel 26 is partitioned by a partition wall 31 into a first supply duct 8 for feeding air which is largely free of fuel and a second supply duct 9 for feeding in an fuel/air mixture. In order to form mixture, fuel is fed in a carburetor 18 to the combustion air which is drawn in. In the exemplary embodiment, the carburetor 18 is configured as a drum-type carburetor and has a throttle element 20 which is configured as a control drum and in which an air channel section 34 and a mixture channel section 33 are formed. The combustion air and the fuel/air mixture flow in a flow direction 36 from the air filter 17 to the cylinder 2 of the internal combustion engine 1.
The first supply duct 8 opens by way of an air inlet 10 on the cylinder 2. The piston 5 has at least one piston pocket 12 which is formed as a depression on the outer side of the piston 5. In the region of the top dead center of the piston 5, the air inlet 10 is connected via the piston pocket 12 to at least one of the transfer windows 15. As a result, combustion air which is largely free of fuel is passed, as advance air, from the first supply duct 8 into the transfer channels 13 and 14. The second supply duct 9 opens by way of a mixture inlet 11 on the cylinder 2. Like the air inlet 10, the mixture inlet 11 is also slot-controlled by the piston 5 and is connected to the interior of the crankcase 4 in the region of the top dead center of the piston 5. In operation, when the piston 5 is situated in the region of top dead center, fuel/air mixture is drawn into the crankcase 4 via the second supply duct 9 and the mixture inlet 11. Combustion air which is largely free of fuel is passed, as advance air, from the first supply duct 8 via the piston pocket 12 into the transfer channels 13 and 14.
During the downward stroke of the piston 5, that is, during the movement of the piston 5 in the direction of the crankcase 4, the fuel/air mixture in the crankcase 4 is compressed. Before the piston 5 reaches its bottom dead center, the transfer windows 15 to the combustion chamber 3 open. Via the transfer channels (13, 14), first of all air which is largely free of fuel flows into the combustion chamber 3 and flushes exhaust gases from a preceding engine cycle through the outlet 16. Subsequently, fresh fuel/air mixture flows in a replenishing manner from the interior of the crankcase 4. During the following upward stroke of the piston 5, first of all the transfer windows 15 and subsequently the outlet 16 are closed by the piston 5. The piston 5 then compresses the fuel/air mixture in the combustion chamber 3, until the fuel/air mixture is ignited in the region of the top dead center of the piston 5. On account of the combustion which follows, the piston 5 is accelerated in the direction of the crankcase 4. As soon as the outlet 16 opens, the exhaust gases flow out of the combustion chamber 3. The transfer windows 15 subsequently open. The air which is largely free of fuel and enters into the combustion chamber 3 via the transfer windows 15 flushes the exhaust gases out of the combustion chamber 3, before fresh mixture from the crankcase 4 flows into the combustion chamber 3 for the next engine cycle.
In the completely closed position of the throttle element 20, a small cross section of at least one of the supply ducts (8, 9) can remain open. In the completely open position of the throttle element 20, a small cross section of at least one of the supply ducts (8, 9) can remain closed by the throttle element 20, with the result that the throttle element 20 reduces the flow cross section of the at least one supply duct (8, 9) even in its completely open position.
As
The throttle element 20 is spring-loaded by a compression spring 25, and the compression spring 25 presses the throttle element 20 in the direction of its completely closed position. Instead of the compression spring 25, a spring which acts in the rotational direction of the throttle element 20 can also be provided. As
In order to start the internal combustion engine 1, the brushcutter 37 has a starter device 46 which is shown diagrammatically in
In
The actuating plate 23 has a recess 49, on which a second ramp 48 is formed. At its end, the recess 49 forms a stop element 50. In the exemplary embodiment, the recess 49 is arranged on that side of the actuating plate 23 which faces the throttle element 20. However, a different arrangement of the recess 49, for example as a groove on the circumference of the actuating plate 23, can also be advantageous. The actuating plate 23 has an actuating edge 66 on its side which faces the throttle element 20. A lever 72 is connected fixedly to the actuating plate 23 and defines a latching element 51. The lever 72 is arranged on that side of the actuating plate 23 which faces away from the throttle element 20. A different design and arrangement of the latching element 51 can also be advantageous.
In order to assume a starting position, the starter device 46 has an actuating unit 52 which can be configured, for example, as a lever or actuating button. The actuating unit 52 has an actuating axis 53. The actuating unit 52 is arranged adjacently with respect to a housing wall 57 of the brushcutter 37. Here, the housing wall 57 can be any desired wall which is connected fixedly to the housing 38 of the brushcutter 37 or to the carburetor housing 19. The actuating unit 52 has a guide part 73. In the operating position 47, the guide part 73 of the actuating unit 52 is at a spacing (a) from the housing wall 57. The actuating unit 52 is preloaded by a spring 58 in the direction of the operating position 47. In the exemplary embodiment, the spring 58 is a helical spring which acts as a torsion spring and a compression spring between the housing wall 57 and the actuating unit 52 and is arranged on the outer circumference of the cylindrical guide part 73. The actuating unit 52 has a latching element 54 which interacts with the latching element 51 on the throttle element 20 in the starting position 63 (shown in
In order to adjust the actuating unit 52 from the operating position 47 which is shown in
As
During the movement of the throttle element 20 in the direction of the pivot axis 35, the adjustment needle 27, which is shown in
In
If, from the starting position 63 which is shown in
As
If the operator applies more throttle from the enrichment position 62, the guide face 60 slides on the first ramp 48 until the position which is shown in
If the operator lets go of the operator-controlled element 42 from the position which is shown in
At least one further ramp can be provided which controls the flow cross section of the fuel opening 28 after the guide element 61 has passed out of the recess 49 and no longer bears against the second ramp 48. The guide face 60 advantageously comes into contact with a further ramp after it has been raised up from the second ramp 48. A plurality of further ramps can be provided which are advantageously used one behind another in a cascade-like manner. During each closing operation of the throttle element 20, the guide face 61 advantageously passes out of one ramp into a ramp which is connected downstream thereof, until the first ramp 64 is reached. As a result, the fuel quantity which is fed in after starting can be controlled in a satisfactory manner.
In the exemplary embodiment, the throttle element 20 is provided which controls both the supply duct 8 and the supply duct 9. However, a separate throttle element can also be provided in the supply duct 8. The position of the throttle element in the supply duct 8 is then advantageously coupled to the position of the throttle element in the supply duct 9.
It is understood that the foregoing description is that of the preferred embodiments of the invention and that various changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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10 2013 009 669.3 | Jun 2013 | DE | national |