DE102016226221A1 - Device for splitting wood - Google Patents

Abstract

Device (10 ") for splitting wood with at least one expansion limb (12) which is rotatably mounted on a wood element (24) to be split for transmitting a splitting force, a spreading element (14) attached to a lower one in an insertion direction of the device ( 10 ") arranged facing the wooden element (24) device end region and is further adapted to transmit a spreading force on the expansion leg (12), and a lifting unit (18") with at least one lifting element (20 ") in the direction of insertion of the device (10 ") is arranged below the expansion element (14) and mechanically coupled to the expansion element (14), wherein the lifting unit (18") is adapted to increase its length a along a longitudinal axis of the device (10 ").

Description

State of the art

The invention relates to a device for splitting wood, a use of this device for splitting wood and a method for splitting wood by means of the device.

The range of mobile devices for splitting wood is manageable. Usually, the force required for splitting is applied mechanically or hydraulically to axes and split hammers by muscle power, to splitting wedges with chain saws and cone splitters.

The wood is mainly split by the introduction of a wedge-shaped tool.

The DE 299 17 010 U1 discloses a wood splitting apparatus having a cutting tool making a recess in the wood and at least one splitting tool engageable in the recess. In this case, the splitting tool can be hydraulically or pneumatically actuated.

From the DE 1 035 069 B a two-legged internal extractor for ball bearings and other annular machine parts is known. Here, the internal extractor is inserted into the interior of the deducted ball bearing and the lower ends of the legs inserted under the workpiece. The legs are spread apart by means of an expansion body to pull off the ball bearing.

Disclosure of the invention

The present invention is a device for splitting wood with at least one expansion leg, which is rotatably supported for transmitting a splitting force on a wood element to be split, a spreader disposed on a lower in an insertion direction of the device the wood element facing device end region and further is to transmit a spreading force on the expansion limb, and a lifting unit with at least one lifting element, which is arranged in the insertion direction of the device below the expansion element and mechanically coupled to the expansion element, wherein the lifting unit is formed, its length a along a longitudinal axis of the device enlarge.

• - Vorsehen einer einen Boden aufweisenden Aussparung in einem zu spaltenden Holzelement;
• - Einbringen einer oben beschriebenen Vorrichtung in den Bereich des Bodens der Aussparung; und
• - Ändern des Betriebszustandes der Hubeinheit von einem ersten Betriebszustand in einen zweiten Betriebszustand, wobei die Hubeinheit im zweiten Betriebszustand eine größere Länge a entlang einer Längsachse der Vorrichtung in Richtung des Bodens der Aussparung aufweist, um eine Druckkraft von dem Hubelement auf den Boden der Aussparung auszuüben und mittels der resultierenden Gegenkraft eine Hubbewegung des Spreizelements entgegen der Einbringrichtung der Vorrichtung zu erzeugen.

The subject of the present invention is furthermore a use of the above-described device for splitting wood as well as a method for splitting wood with the following steps:

• Providing a recess having a bottom in a wood element to be split;
• - introducing a device described above in the region of the bottom of the recess; and
• Changing the operating state of the lifting unit from a first operating state to a second operating state, wherein the lifting unit in the second operating state has a greater length a along a longitudinal axis of the device in the direction of the bottom of the recess to exert a compressive force from the lifting element to the bottom of the recess and by means of the resulting counterforce to produce a lifting movement of the expansion element against the direction of insertion of the device.

Under a device for splitting wood can be understood in the context of the present invention, a wood splitting device, with the wood elements, especially meter wood, can be split.

The device has at least one expansion limb. However, it is advantageous if the device has two expansion limbs, which are rotatably mounted such that the rotational movement of the two expansion legs takes place in opposite directions of rotation.

In the context of the present invention, a spreader leg can be understood to mean an element which is rotatably mounted about one or more bearing points. The expansion leg can be elongated. That is, in other words, that the expansion leg is formed longer in the direction of insertion of the device than radially to the direction of insertion of the device. Under a rotatable mounting can be understood in the context of the present invention, a storage that allows a rotational movement about a bearing point. The rotational movement may also have a translational component. In other words, the bearing point can be movable. Moreover, it is advantageous if in addition the bearing point is formed in an end region of the expansion leg. In particular, it is advantageous if the bearing point is formed in an upper end region of the expansion limb facing away from the wood element in the direction of insertion of the device. This configuration of the storage increases the maximum spread of the expansion limb.

The expansion element is movable, in particular arranged translationally movable and formed by its shape, energy and / or force efficient to transfer a spreading force on a spreader leg. The expansion element can, for example be at least partially wedge-shaped or designed as a riving knife.

Due to the rotatable mounting of the expansion limb and the corresponding movable arrangement of the expansion element, a translational movement of the expansion element relative to the expansion limb can be converted into a rotational movement of the expansion limb. The translational movement of the expansion element may be a purely linear or axial movement. However, the translational movement may also have a superimposed rotational component or movement in addition to the linear movement. Accordingly, the expansion element can also carry out a rotational movement, for example a helical movement, as a result of a translatory movement and thus move in the context of this invention translationally relative to the expansion limb. As a result, an expanding force is transmitted from the spreader to the spreader leg, which in turn a splitting force is transmitted from the spreader leg to the wood element.

In the context of the present invention, a spreading force can be understood as meaning a force which causes a rotational movement of a spreader leg about its bearing point.

In the context of the present invention, a splitting force can be understood as meaning a force which can divide or split a wood workpiece, in particular a wood element, into at least two parts. That is, in other words, the nip force is formed in magnitude and direction so as to result in a division of the wood member. The splitting force has at least one radial force component, that is, a force component perpendicular to the direction of movement of the expansion element.

In the context of the present invention, a recess in a wooden element can be understood to mean a spatially limited area in the wooden element. The recess may be formed as a gap and / or generated by material removal. The recess has a bottom. In other words, the recess does not completely penetrate the wood element. The recess may be formed, for example, as a blind hole.

In the context of the present invention, a longitudinal axis of a device can be understood to mean an axis which extends in the longitudinal direction to the longest extent of the device. For example, in the context of the present invention, the longitudinal axis can run in or counter to the direction of insertion of the device.

Under a lifting unit can be understood in the context of the present invention, a unit that can change its length a along the longitudinal axis of the device. In particular, the lifting unit is designed to increase its length a along the longitudinal axis of the device. In this case, the lifting unit has at least one lifting element. In addition, the lifting unit may have one or more intermediate elements. By at least one relative movement between the expansion element, lifting element and intermediate element, the lifting unit can increase its length a. The lifting unit can be mechanically operated. Accordingly, the lifting unit can be activated or activated by means of a force, for example a compressive force, a tensile force and / or a fluidic force, in order to increase its length a along the longitudinal axis of the device. The lifting unit can also be operated electrically. Accordingly, the lifting unit can be activated or activated by means of an electrical signal to increase its length a along the longitudinal axis of the device.

By means of the device according to the invention and the method according to the invention, it is now possible to carry out the splitting of wood in a particularly energy-efficient and force-efficient manner. This is achieved in particular by producing a recess in a wood element to be split and by splitting the wood element as two successive process steps. In this case, the production of the recess in the wooden element can be carried out in a first method step with any tool found suitable by the person skilled in the art. In a second method step, the device can be introduced without any effort into the recess in the wood element up to or in the vicinity of the bottom of the recess. By a subsequent activation or loading of the lifting unit with a force, this increases its length along the longitudinal axis of the device, so that the lifting element exerts a compressive force on a bottom of the recess. By means of the resulting counterforce of the bottom of the recess on the lifting element, a lifting movement of the expansion element against the insertion direction of the device can be generated in order to spread apart the expansion element and thus to split the wood element.

It is advantageous if the lifting element is arranged displaceably relative to the spreading element along the longitudinal axis of the device in order to produce the increase in the length a. By a displacement along the longitudinal axis causes a distance-increasing relative movement of the lifting element and expander directly and thus in an efficient manner an increase in length of the lifting unit. In addition, this embodiment of the device is particularly easy to implement.

Furthermore, it is advantageous if the lifting element and the expansion element are mechanically coupled by means of at least one intermediate element. It is advantageous here if the intermediate element is selected from the group consisting of: pipe element, bolt element, actuator element, lifting table element, spring element, and bag-like compressed gas element. As a tubular element and / or bolt element, the intermediate element has a constant length. The increase in length of the lifting unit in this case results from a relative movement of the intermediate element and the expansion element and / or the intermediate element and the lifting element. As an actuator element and / or spring element and / or lifting table element and or bag-like compressed gas element formed, the intermediate element has a variable length. The increase in length of the lifting unit can in this case result at least partially from the increase in length of the intermediate element.

Moreover, it is advantageous if the intermediate element and the lifting element and / or the intermediate element and the expansion element are telescopically movable relative to each other along the longitudinal axis. For example, the lifting element and / or the intermediate element may be formed as a telescopic cylinder. Alternatively, the lifting element and / or the intermediate element may be telescopically extendable from the expansion element. Due to the telescopic design, the maximum stroke length of the expansion element can be increased. That is, in other words, that the spreader after the introduction of the device by a greater distance against the direction of insertion of the device is movable and thus the spread of the spreader leg can be increased.

It is also advantageous if the intermediate element has at least two mutually displaceable individual elements in order to produce the increase in the length a. For example, the individual elements can be designed as piston and housing elements. In the context of the present invention, a housing element can be understood to be an element which has at least one recess into which a piston element can be arranged so that it can be supported. In the context of the present invention, a piston element can be understood to be an element which can be arranged in the recess of a housing element and is made movable at least partially out of the housing element by transmitting a compressive force. The relative movement of the individual elements can take place along or transversely to the longitudinal axis of the device. Two or more individual elements can be designed and arranged, for example, as a working cylinder. The individual elements can be connected directly or indirectly to the power transmission unit. The individual elements can advantageously be used for targeted control of the increase in length of the lifting unit.

It is advantageous if the device has a power transmission unit, which is connected to the lifting unit and is further configured to transmit a compressive force to the lifting element. Here, the power transmission unit can be non-positively or positively or materially connected to the lifting unit. The power transmission unit may in particular be connected to the lifting element and / or the spreading element and / or the intermediate element. In particular, the power transmission unit can be connected to one or more individual elements. In the context of the present invention, a force transmission unit can be understood to mean a unit which is designed to transmit a compressive force. The power transmission unit may extend from an upper, in the direction of insertion of the device facing away from the wood element device end region along the longitudinal axis of the device to the lifting unit. Thus, by means of the power transmission unit targeted and controlled a compressive force can be transmitted to the lifting element of the introduced into the recess in the wood element device. In this case, the pressure force can be transferred to the device in a particularly simple and practical manner at an upper end region of the power transmission unit facing away from the direction of introduction of the device of the lifting unit.

Moreover, it is advantageous if the lifting unit has a pressure chamber which is fluidically connected to the power transmission unit. In the context of the present invention, a pressure chamber can be understood as meaning an element which is at least partially bounded by a wall. Here, the pressure chamber can be filled at least partially with a pressurized fluid, for example by means of the fluidically connected power transmission unit. The pressure chamber may have a fixed pressure chamber wall and a pressure chamber wall movable relative thereto. The fixed pressure chamber wall may be a portion of the gap element and / or the intermediate element. The movable pressure chamber wall may be a portion of the lifting element and / or the intermediate element. Accordingly, the pressure chamber may have one or more openings through which the lifting element or the intermediate element or the expansion element can be at least partially introduced into the pressure chamber.

In the context of the present invention, a fluid can be understood as meaning a gas or a liquid. In the context of the present invention, a hydraulic fluid may be a hydraulic fluid, in particular a hydraulic fluid Hydraulic oil to be understood, wherein the hydraulic fluid is adapted to transmit a hydrostatic force, in particular a compressive force. In the context of the present invention, a pneumatic fluid can be understood as meaning a gas, in particular a pressurized gas such as, for example, compressed air. In this case, the pressure chamber may be formed, for example, part of a housing element of a hydraulic cylinder and / or pneumatic cylinder or as a hydraulic cylinder and / or pneumatic cylinder.

Furthermore, it is advantageous if the force transmission unit has at least one fluid channel which extends along the direction of introduction of the device from an upper end region of the force transmission unit facing away from the wooden element in the direction of introduction of the device to the lifting unit. Accordingly, the fluid channel forms a fluidic connection between the upper end region of the power transmission unit and the lifting unit.

It is also advantageous if the force transmission unit is designed to be connectable to a fluidic pressure reservoir. Preferably, the upper end region of the force transmission unit can be connected to the fluidic pressure reservoir. It is particularly advantageous if at least one fluid channel is connectable to the fluidic pressure reservoir at the upper end region of the force transmission unit, so that the fluid channel transmits a pressure force to the lifting unit by means of a pressurized fluid. The pressure reservoir may be formed, for example, as a hydraulic pump or pneumatic pump.

Advantageously, the fluidic pressure force in the region of the pressure chamber can be transmitted to the lifting element and / or an intermediate element. The fluidic pressure force can also be transmitted to one or more individual elements of the intermediate element.

In the context of the present invention, a fluid channel can be understood as meaning a channel-shaped structure which is designed to direct a fluid, in particular a pressurized fluid, from an initial region of the fluid channel into an end region of the fluid channel. For example, the fluid channel may comprise a tube element and / or a tube element or be formed as a tube element and / or tube element.

With this configuration and arrangement, a fluidic pressure force can be transmitted from the upper end region of the power transmission unit to the lifting unit. The spreading of the expansion limbs can be performed controlled by the transfer of a fluidic pressure force on the lifting unit by means of the fluid channel even at great forces. In addition, a device with a fluid channel for hydraulic fluids due to the self-lubrication of the sliding movable elements by the hydraulic fluid to a particularly long life. By means of the fluidic pressure reservoir, the strength of the fluidic pressure on the power transmission unit and consequently on the lifting unit can be adjusted and kept constant over a large working range within the scope of the application-specific accuracy required. By connecting the power transmission unit with the fluidic pressure reservoir, the splitting force necessary for splitting the wood element can be applied in a particularly simple manner via the fluidic pressure force.

It is also advantageous if the lifting element comprises a plate element and / or a spring element and / or a bag-like compressed gas element or at least consists of one of these elements. For example, the plate member may have a circular cross section in the plane perpendicular to the longitudinal axis of the device. The plate member may be arranged movable relative to the spreader to produce an increase in the length a of the lifting unit. The spring element can be biased, for example, before the introduction of the device into the recess of the wood element. By activating or triggering mechanism, the spring after the introduction of the device can be relaxed in the recess and transferred from the spring force length increase of the spring by means of the force applied from the bottom of the recess counterforce in a lifting movement of the expansion element. The spring element may be formed, for example, as a metal spring. The bag-like compressed gas element can increase its volume and in particular its length along the longitudinal axis of the device after the introduction of the device into the recess by transferring compressed gas into the compressed gas element by means of the power transmission unit. In the context of the present invention, a compressed gas can be understood as meaning a compressed gas or a compressed gas mixture. The bag-like compressed gas element may be formed, for example, as an airbag-like airbag. By these embodiments, the device has a particularly simple construction.

For a particularly robust and at the same time simple design, it is advantageous if the intermediate element has at least one helical spring element or is designed as a helical spring element, wherein the spring element along the insertion direction of the device can be relaxed to produce the increase in the length a. The helical spring element can at an upper in the direction of insertion of the device facing away from the wood element end of the Intermediate element be connected to the expansion element. The helical spring element may be connectable to the lifting element at a lower end of the intermediate element facing the wooden element in the direction of insertion of the device. It is particularly advantageous if the helical spring element can be relaxed along the direction of insertion of the device. Here, the helical spring element can be biased before the introduction of the device into the wood to be split element. The helical spring element may be formed as a helical spring. The coil spring may be made of metal or another material deemed suitable by the skilled person.

Moreover, it is advantageous if, by means of a support element when transmitting the tensile force on the expansion element for spreading the expansion leg, a counterforce is applied to the expansion leg in the direction of insertion of the device. The support element may be sleeve-shaped and / or disc-shaped. As a result of the support element, a movement of the expansion limb against the direction of insertion of the device is suppressed in a movement of the expansion element counter to the direction of insertion of the device. If the support element is sleeve-shaped or formed as a sleeve, the radial movement of the spreader arms or of the bearing points of the spreader arms is limited, whereby a lever effect can be achieved. If the support element is disc-shaped, then the expansion limbs are connected to one another via a common pivot point, which is preferably arranged in an upper end region of the expansion limb.

list of figures

• 1a - 1d eine schematische Darstellung einer erfindungsgemäßen Vorrichtung mit einem hydraulischen Teleskopzylinder;
• 2a - 2d eine schematische Darstellung einer erfindungsgemäßen Vorrichtung mit einem hydraulischen Scherenhubtisch;
• 3 eine schematische Detailansicht des Scherenhubtisches aus 2;
• 4a - 4d eine schematische Darstellung einer erfindungsgemäßen Vorrichtung mit einer Schraubenfeder; und
• 5 ein Ablaufdiagramm eines Verfahrens zum Spalten von Holz.

The invention will now be described by way of example with reference to the accompanying drawings. Show it:

• 1a - 1d a schematic representation of a device according to the invention with a hydraulic telescopic cylinder;
• 2a - 2d a schematic representation of a device according to the invention with a hydraulic scissor lift;
• 3 a schematic detail view of the scissor lift from 2 ;
• 4a - 4d a schematic representation of a device according to the invention with a coil spring; and
• 5 a flow diagram of a method for splitting wood.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similar acting, wherein a repeated description of the elements is omitted.

In 1a to 1d is a device for splitting wood, that is, a wood splitter, shown in their entirety by the reference numeral 10 is provided.

The wood splitting device 10 has two expansion legs 12 , a spreading element 14 , a power transmission unit 16 and a lifting unit 18 on.

The expansion legs 12 are elongated. That is, in other words, that the expansion legs 12 in the direction of insertion 22 the wood splitting device 10 are formed longer than radially to the insertion direction 22 the wood splitting device 10 , The expansion legs 12 consist of the halves of a longitudinally halved straight hollow cylinder. In a lower direction of insertion 22 the wood splitting device 10 a wooden element 24 facing area 26 the expansion leg 12 have the expansion legs 12 straight bevels 28 on. The bevels 28 on the expansion legs 12 are designed so that in the unspread state of the wood splitting device 10 between the bevels 28 a cavity 30 is trained.

The expansion legs 12 are for transmitting a splitting force on the wood element to be split 24 one bearing point each 32 rotatably mounted. Here are the bearing points 32 in an upper, in the insertion direction 22 the wood splitting device 10 the wooden element 24 opposite end region 34 the expansion leg 12 arranged. In this embodiment, the bearing points 32 spatially fixed. In general, the bearing points 32 However, be designed to be movable.

The spreading element 14 is designed as a wedge with a round base. The shape of the expansion element 14 is complementary to the shape of between the bevels 28 the expansion leg 12 trained cavity 30 , This allows the spreader 14 in the unspread state of the expansion leg 12 with full volume in the cavity 30 be introduced. The spreading element 14 points along the direction of insertion 22 the wood splitting device 10 a longitudinal bore through which the power transmission unit 16 is guided.

The power transmission unit 16 is elongated and formed in its basic form as a straight hollow cylinder. The cylindrical cavity of the hollow cylinder is used as a fluid channel 36 educated. The fluid channel 36 is therefore along the longitudinal axis of the power transmission unit 16 from an upper in the insertion direction 22 the wood splitting device 10 the wood element 24 opposite end region 38 the power transmission unit 16 to a lower in the insertion direction 22 the wood splitting device 10 the wooden element 24 facing end region 40 the power transmission unit 16 educated. Thus, the fluid channel forms 36 a hydraulic pipe connection 36 between the upper end area 38 the power transmission unit and the lower end portion 40 of the power transmission unit. The fluid channel 36 is designed to transmit a hydraulic pressure force by means of a hydraulic oil. The power transmission unit 16 can in its upper end area 38 be connected to a hydraulic pump, not shown.

The lifting unit 18 is at a lower in the insertion direction 22 the wood splitting device 10 the wooden element 24 facing wood splitter end area 56 arranged. The lifting unit 18 has a lifting element 20 and four intermediate elements 44 . 46 . 48 . 50 on. The lifting element 20 is designed as a circular plate element 20 educated.

The intermediate elements 44 . 46 . 48 . 50 form a three-stage hydraulic telescopic cylinder 42 out. The intermediate elements 44 . 46 . 48 . 50 or the telescopic cylinder 42 is between the spreader 14 and the lifting element 20 is arranged. Accordingly, the lifting element 20 and the spreader 14 by means of telescopic cylinders 42 trained intermediate elements 42 mechanically coupled.

The intermediate elements 44 . 46 . 48 . 50 consist of a housing 44 and three piston elements 46 . 48 . 50 , The piston elements 46 . 48 . 50 are designed to run into each other and in the housing 44 arranged concentrically. The piston element 50 is directly with the lifting element 20 connected. The relative movement takes place between the housing 44 and the piston elements 46 . 48 . 50 and the lifting element 20 one-dimensionally along the longitudinal axis of the wood splitting device 10 ,

The piston elements 46 . 48 . 50 are fluidly connected. The interiors of the housing 44 and the piston elements 46 . 48 . 50 are as a pressure chamber 54 educated. That is, in other words, that the piston elements 46 . 48 . 50 by transmitting a hydraulic pressure force telescopically relative to the housing 44 can be extended.

The housing 44 is at its upper in Einbringrichtung 22 the wood splitting device 10 the wooden element 24 opposite end 60 with the expansion element 14 material connected. The housing 44 is with the hydraulic pipe connection 36 the power transmission unit 16 hydraulically connected. Thus, the piston elements 46 . 48 . 50 in the direction of insertion 22 the wood splitting device 10 be extended.

The lifting element 20 is with the piston element 50 with the smallest diameter at the bottom in the insertion direction 22 the wood splitting device 10 the wood element 24 facing the end 62 material connected. The diameter of the lifting element 20 is greater than the diameter of the piston element 50 with the smallest diameter. Accordingly, the lifting element 20 and the spreader 14 slidably disposed along the longitudinal axis to increase the length a of the lifting unit 18 to create. By transferring a hydraulic pressure force to the telescopic cylinder 42 by means of the power transmission unit 16 can the lifting unit 18 its length a along the longitudinal axis of the wood splitting device 10 enlarge.

Sequence-like is in 1a to 1d represented as by means of the wood splitting device 10 the wooden element 24 can be split. 1a shows the provision of the wood splitting device 10 at an upper in the insertion direction 22 the wood splitting device 10 the wooden element 24 opposite end region 66 a recess 64 , The wood splitting device 10 is first with the lifting element 20 perpendicular to the surface of the wood element to be split 24 arranged, at which the recess 64 located. This is the wood splitting device 10 with its longitudinal axis preferably in the direction of the longitudinal axis of the recess 64 arranged.

1b shows how the wood splitting device 10 into one for splitting the wood element 24 optimal penetration depth into the wood element 24 is introduced. Preferably, the wood splitting device becomes 10 here to a floor 68 the recess 64 brought in. The wood splitting device 10 can after insertion at the upper end 38 the power transmission unit 16 be fluidly connected to a hydraulic pump, not shown.

In 1c is shown as by transmitting a hydraulic pressure force across the power transmission unit 16 on the lifting unit 18 the piston elements 46 , 48, 50 and the lifting element 20 relative to the housing 44 telescopic in the direction of insertion 22 the wood splitting device 10 be extended. The bottom 68 of the recess 64 brings in this case a counterforce on the lifting element 20 on. By this counter force causes the telescopic relative movement of the piston elements 46 . 48 . 50 a lifting movement of the expansion element 14 in the stroke direction 70 that is opposite to the direction of insertion 22 the wood splitting device 10 , By the movement of the expansion element 14 becomes a spreading force on the expansion leg 12 exerted, for spreading the expansion legs 12 in spreading direction 72 leads. The spreading of the expansion legs 12 produces one at least proportionally perpendicular to the insertion direction 22 of the wood splitting device 10 acting splitting force on the wooden element 24 ,

1d shows the wood splitting device 10 with maximally spread spreader legs 12 and that by means of the wood splitting device 10 in two parts split wooden element 24 , For maximum spreading of the expansion leg 12 becomes the expansion element 14 by means of the pressure force up to the area of the bearing points 32 emotional.

In 2a to 2d is another embodiment of a wood splitting device 10 ' shown at the intermediate element 52 as scissor lift table 52 is trained.

The scissor lift table 52 has four relatively movable rod elements 74 on. Two rod elements each 74 are together at one end 76 rotatably mounted and form a two-rod element. Each of the two two-bar elements is at a first end region 78 with the lower in the insertion direction 22 the wooden element 24 facing Spreizelementende 82 rotational and perpendicular to the direction of insertion 22 the wood splitting device 10 ' linked translationally connected. Each of the two two-bar elements is at a second end region 80 with the lifting element 20 rotational and perpendicular to the direction of insertion 22 the wood splitting device 10 ' linked translationally connected.

Sequence-like is in 2a to 2d represented as by means of the wood splitting device 10 ' the wooden element 24 can be split. 2a shows the provision and application of the wood splitting device 10 ' to the wood element 24 , analogous to that in 1a shown embodiment takes place. 2 B shows analogously to 1b the introduction of the wood splitting device 10 'in the vicinity of the soil 68 the recess 64 of the wooden element 24 , That is, in other words, in one for splitting the wood element 24 optimal penetration depth.

In 2c is shown as by transmitting a hydraulic pressure force to the lifting unit 18 ' by means of the power transmission unit 16 an extension movement of the scissor lift 52 he follows. By means of a not shown here and in 3 closer explained hydraulic cylinder caused extension movement of the scissor lift 52 becomes the lifting element 20 ' in the direction of insertion 22 the wood splitting device 10 ' extended. The floor 68 the recess 64 brings in this case a counterforce on the lifting element 20 ' out. By this counter force causes the extension movement of the scissor lift 52 a lifting movement of the expansion element 14 in the stroke direction 70 that is opposite to the direction of insertion 22 the wood splitting device 10 ' , Analogous to 1c causes the lifting movement of the expansion element 14 the spreading of the expansion legs 12 in spreading direction 72 ,

2d shows the wood splitting device 10 ' with a extended scissor lift 52 at the end of the splitting process and by means of the wood splitting device 10 ' in two parts split wooden element 24 ,

3 showed a schematic representation of the scissor lift 52 out 2a-d with an in 2a-d not shown hydraulic cylinder 84 , The hydraulic cylinder 84 has a piston element 86 and a housing member 88 on. That is, in other words, that the hydraulic cylinder 84 two mutually displaceable individual elements 86 . 88 having. The housing element 88 has a pressure chamber 54 ' on. By transmitting a hydraulic pressure force to the piston element 86 by means of the power transmission unit 16 in the pressure chamber 54 ' For example, the scissor lift table 52 can have its length and thus the length a of the lifting unit 18 ' along the longitudinal axis of the wood splitting device 10 ' enlarge.

The scissor lift table 52 has four relatively movable rod elements 74 on. Two rod elements each 74 are together at one end 76 rotatably mounted and form a two-rod element. Each of the two two-bar elements is at a first end region 78 with the lower in the insertion direction 22 the wooden element 24 facing Spreizelementende 82 rotational and perpendicular to the direction of insertion 22 the wood splitting device 10 ' linked translationally connected. Each of the two two-bar elements is at a second end region 80 with the lifting element 20 rotational and perpendicular to the direction of insertion 22 the wood splitting device 10 ' linked translationally connected.

In 4a to 4d is another preferred embodiment of a wood splitting device 10 " shown at the intermediate element 52 ' as a coil spring 52 ' is trained. The coil spring 52 ' is between the spreader 14 and the lifting element 20 arranged. The coil spring 52 'is at its upper in the insertion direction 22 the device 10 " the wooden element 24 opposite end 78 ' with the expansion element 14 connected. The coil spring 52 is at its lower in Einbringrichtung 22 the device 10 " the wooden element 24 facing the end 80 ' with the lifting element 20 " connected.

The coil spring 52 is designed as an elastic metal spring. The coil spring 52 may be biased in a first operating state.

By subsequently activating a triggering mechanism can coil spring 52 in be transferred to a second operating state in which the coil spring 52 is relaxed. By relaxing the coil spring 52 becomes an increase in the length a of the lifting unit 18 " generated. The at the relaxation of the coil spring 52 Released spring energy is in a lifting movement of the expansion element 14 in the stroke direction 70 for spreading the spreader leg 12 transferable.

Sequence-like is in 4a to 4d represented as by means of the wood splitting device 10 " the wooden element 24 can be split. 4a shows the provision and application of the wood splitting device 10 " to the wood element 24 , analogous to those in 1a and 2a shown embodiments. Here is the coil spring 52 biased and has a compared to the relaxed state of the coil spring 52 shortened length along the direction of insertion 22 the wood splitting device 10 " on. 4b shows analogously to 1b and 2 B the introduction of the wood splitting device 10 " near the bottom 68 the recess 64 of the wooden element 24 , That is, in other words, in one for splitting the wood element 24 optimal penetration depth.

In 4c It is shown how activating the trigger mechanism, the coil spring 52 relaxed while keeping their length in the direction of insertion 22 the wood splitting device 10 " increased. By relaxing the coil spring 52 is the lifting element 20 " also in the direction of insertion 22 the wood splitting device 10 ' extended. The floor 68 the recess 64 brings in this case a counterforce on the lifting element 20 " out. By this reaction force causes the relaxation of the coil spring 52 a lifting movement of the expansion element 14 in the stroke direction 70 that is opposite to the insertion direction 22 of the wood splitting device 10 " , Analogous to 1c causes the lifting movement of the expansion element 14 the spreading of the expansion legs 12 in spreading direction 72 ,

2d shows the wood splitting device 10 ' with a completely relaxed coil spring 52 at the end of the splitting process and by means of the wood splitting device 10 " in two parts split wooden element 24 ,

5 shows a flowchart of a method 100 for splitting wood by means of the wood splitting device 10 . 10 ' , The method comprises a step 102 the provision of the wood splitting device 10 , 10`. Furthermore, the method comprises 100 one step 104 the introduction of the wood splitting device 10 . 10 ' in a recess 64 a wood element to be split 24 , Furthermore, the method comprises a step 106 the transmission of a compressive force in the direction of insertion 22 the wood splitting device 10 . 10 ' by means of the power transmission unit 16 on the lifting element 20 . 20 ' to get through from the ground 68 the recess 64 applied counterforce a lifting movement of the expansion element 14 in the stroke direction 70 to produce and by spreading the expansion legs 12 a splitting force on the wood element to be split 24 transferred to.

If an exemplary embodiment comprises a "and / or" link between a first feature and a second feature, then this is to be read so that the embodiment according to one embodiment, both the first feature and the second feature and according to another embodiment either only first feature or only the second feature.

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 29917010 U1 [0004]
• DE 1035069 B [0005]

Claims (15)

Device for splitting wood with - at least one expansion limb (12), which is rotatably mounted on a wood element (24) to be split for transferring a splitting force, and - a spreading element (14) attached to a lower one in an insertion direction (22) Device (10; 10 '; 10 ") the wood element (24) facing device end region (56) arranged and further adapted to transfer a spreading force on the expansion leg (12), characterized by a lifting unit (18; 18';18") with at least one lifting element (20; 20 '; 20 ") which is arranged in the introduction direction (22) of the device (10; 10';10") underneath the spreading element (14) and mechanically coupled to the spreading element (14) the lifting unit (20; 20; 20 ") is designed to increase its length a along a longitudinal axis of the device (10; 10 ';10"). Device (10; 10 '; 10 ") after Claim 1 , characterized in that the lifting element (20; 20 '; 20 ") is slidably disposed relative to the spreader (14) along the longitudinal axis to produce the increase in the length a. Device (10; 10 '; 10 ") after Claim 1 or 2 , characterized in that the lifting element (20; 20 ': 20 ") and the expanding element (14) are mechanically coupled by means of at least one intermediate element (44; 46; 48; 50; 52). Device (10; 10 '; 10 ") after Claim 3 , characterized in that the intermediate element (44; 46; 48; 50; 52) as a tubular element (42; 44; 46; 48; 50) and / or bolt element and / or actuator element and / or lifting table element (52) and / or spring element (52) and / or bag-like compressed gas element is formed. Device (10) according to Claim 3 or 4 characterized in that the intermediate element (44; 46; 48; 50; 52) and the lifting element (20) and / or the intermediate element (44; 46; 48; 50; 52) and the spreader element (14) are telescoping along the longitudinal axis are movable against each other. Device (10; 10 ') according to Claim 3 to 5 , characterized in that the intermediate element (44; 46; 48; 50; 52) has at least two individual elements (86, 88) which can be displaced relative to one another in order to produce the increase in the length a. Device (10; 10 '; 10 ") according to one of the preceding claims, characterized by a force transmission unit (16) which is connected to the lifting unit (18; 18';18") and is further configured to apply a compressive force to the lifting element (20 20 ', 20 "). Device (10; 10 ') according to Claim 7 , characterized in that the lifting unit (18; 18 ') has a pressure chamber (54; 54') which is fluidically connected to the power transmission unit (16 '). Device (10; 10 ') according to Claim 7 or 8th , characterized in that the force transmission unit (16) has at least one fluid channel (36) extending along the direction of insertion (22) of the device (10, 10 ') from an upper in the insertion direction (22) of the device (10, 10'). extending from the wooden element (24) end region (38) of the power transmission unit (16) up to the lifting unit (18, 18 ') extends. Device (10; 10 ') according to Claim 7 to 9 , characterized in that the force transmission unit (16) is connectable to a fluidic pressure reservoir. Device (10; 10 '; 10 ") according to one of the preceding claims, characterized in that the lifting element (20; 20';20") comprises a plate element and / or a spring element and / or a bag-like compressed gas element or at least one of these Elements exists. Device (10 ") according to one of the preceding claims, characterized in that the intermediate element (52) has at least one helical spring element or is designed as a helical spring element, wherein the spring element along the insertion direction (22) of the device (10") is releasable, to produce the increase in length a. Device (10; 10 '; 10 ") according to one of the preceding claims, characterized in that the device (10; 10';10") has a force transmission unit (16) and two expansion limbs (12) which are rotatably mounted in such a manner, that the rotational movement of the two expansion limbs (12) takes place in opposite directions of rotation. Use of the device (10; 10 '; 10 ") according to any one of the preceding claims for splitting wood. Method (100) for splitting wood, comprising the steps of: - providing (102) a recess (64) having a bottom (68) in a wood element (24) to be split; - introducing (102) a device (10; 10 '; 10 ") according to one of Claims 1 to 13 in the region of the bottom (68) of the recess (64); and - Changing (104) the operating state of the lifting unit (18; 18 '; 18 ") from a first operating state to a second operating state, wherein the lifting unit (18; 18';18") in the second operating state has a greater length a along a longitudinal axis of the device (10; 10 ', 10 ") towards the bottom (68) of the recess (64) for exerting a compressive force from the lifting element (20; 20';20") on the bottom (68) of the recess (64) and by means of the resulting counterforce to generate a lifting movement of the expansion element (14) against the introduction direction (22) of the device (10, 10 ').

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