DE102009045799A1 - Machine tool and method for cooling a machine tool - Google Patents

Abstract

The invention relates to a machine tool with a housing (12) and a tool holder (14), arranged movably on the housing (12), for receiving an insert tool (16). The machine tool also has a drive device (22), which is received in the housing (12) and has a drive unit (18, 48, 50) and a gear unit (20), for driving the insert tool (16), which generates waste heat during operation. It is proposed that the gear unit (16) comprises at least one heat sink (88).

Description

State of the art

The invention relates to a machine tool, in particular a hand tool according to the preamble of claim 1.

There are already known machine tools with a housing, a tool holder movably arranged on the housing for receiving an insertion tool and a drive device accommodated in the housing for driving the tool. In an operation of the drive device, which has a drive unit and a gear unit, a waste heat is generated. In particular, in known drills and / or impact hammers a significant amount of waste and / or waste heat is generated during operation. Particularly high amounts of heat and thus high temperatures arise in a front region of these hand tool machines, where a plurality of heat sources is arranged. These are, for example, a heat of compression from an air cushion of a percussion mechanism of the pipe and / or percussion hammer, occurring impact losses from the impact processes between elements of the percussion mechanism, possible friction losses inside the percussion mechanism by relative movements between elements of the percussion mechanism and / or friction losses of other moving components of the impact mechanism. and / or percussion hammer. In order to limit a thermal load on the internal components, the heat loss must be derived to a sufficient extent from a housing interior to the outside. A heat transfer takes place here mainly via heat pipe. In the example of the known drilling and / or impact hammers a large part of the heat generated in the percussion must be dissipated via two bearings of the hammer tube belonging to the percussion. Due to the design of these bearings but only small contact surfaces or contact surfaces, so that the heat transfer surface and thus the transmittable heat are rather low. Consequently, the thermal load of the percussion components lying in the housing in the known designs of drills and / or impact hammers is particularly high.

The heat loss to the exterior surface of the percussion unit is largely dissipated to the environment by convection. An air mass flow required for convection is usually generated by a fan connected to the drive unit. In order to guide the air mass flow to a front region of the rotary hammer and / or percussion hammer and to protect the operator from harmful contact temperatures, a striking mechanism housing surrounding the impact mechanism is often surrounded by an additional plastic housing. But since the hottest part of this percussion gear housing is often at the end of the cold chain, there is only insufficient heat transfer to the outside at this point.

This is for example off DE 10 2004 058 696 A1 known to bring about the so-called Venturi nozzle effect effectively air in the front areas. The utilization of this effect requires a relatively complex construction of the hammer drill.

Disclosure of the invention

Advantages of the invention

The machine tool according to the invention, in particular hand tool machine, with the features of the main claim has the advantage that the gear unit comprises at least one heat sink. By the heat sink can be advantageously achieved that occurring in the transmission unit waste heat can be delivered particularly effectively to a surrounding air mass flow.

The measures listed in the dependent claims, advantageous refinements and improvements of the main claim features.

An effective and space-saving design can be achieved in that the gear unit comprises an at least rotatable shaft which is at least partially surrounded by the heat sink. It may be of particular advantage when the rotatable shaft is mounted in the heat sink.

In a particularly effective embodiment, the heat sink encloses the at least rotatable shaft substantially coaxially.

If the heat sink is at least substantially non-rotatably connected, preferably non-rotatably connected to the at least rotatable shaft, then a heat transfer can proceed even more effectively. In a particularly preferred embodiment, the heat sink is designed as a centrifugal disk.

In order to improve the efficiency of the transmission element designed as a heat sink with respect to a removal of the waste heat, the transmission element designed as a heat sink has at least one subregion provided with cooling fins.

In a further advantageous development, the heat sink has at least one heat-absorbing connection region. Under a heat-absorbing connection area is In this case, in particular, a region on the heat sink is understood, at which the latter is in contact, preferably in direct contact, with a heat-emitting body, so that the lowest possible heat transfer resistance is produced. A direct contact can be made, for example, by positive and / or positive and / or cohesive connection. In a particularly simple embodiment, the contact is formed as a press fit. Alternatively or additionally, in a further embodiment, a heat-conducting substance such as, for example, a heat-conducting paste can advantageously be used in the connection region.

In a preferred embodiment of the machine tool at least parts of the gear unit are arranged in a gear housing, which is accommodated in the housing. Preferably, the gear housing is made of a metallic material, in particular steel.

In a particularly advantageous embodiment, the gear housing has at least on one surface at least one gas-permeable surface structure in a surface direction. In this case, a surface direction is understood to mean, in particular, an extension direction of the surface. In this case, a gas-permeable surface structure is to be understood as meaning, in particular, a structure which opposes, to a gas flowing in the structure, the lowest possible, preferably almost vanishing, resistance. The inflowing gas may preferably be air. In a particularly simple embodiment, the surface structure may be formed as at least one overflow groove.

For a particularly effective removal of the waste heat in the housing at least one air inlet opening is provided, via which a cooling air flow for the removal of at least a portion of the waste heat can flow into the housing. Furthermore, at least one air outlet opening is provided in a transition region between the tool holder and the housing, via which at least a fraction of the cooling air flow can exit.

In order to prevent any damage by dust penetrating, designed as a heat sink gear element has at least a dust-tight sealing point. This dust-tight sealing point prevents direct contact of the gear unit with the cooling air flow at least as far as possible, preferably almost completely.

In a preferred embodiment, the at least rotatable shaft is an at least rotatable working spindle, in particular a hammer tube. In a particularly preferred embodiment, the machine tool according to the invention is a hand tool, in particular a drill and / or chisel hammer.

In a further aspect, the invention relates to a method for cooling a machine tool, in particular a hand tool, which has a drive device accommodated in a housing, having a drive unit and a gear unit. In one operation of the drive device, a waste heat is generated, wherein a cooling air flow to at least a portion of the waste heat flows into the housing via at least one air inlet opening provided in the housing. It is proposed that at least part of the cooling air flow flows over a heat sink arranged on a rotatable shaft of the transmission unit.

Description of the drawings

An embodiment of the invention is illustrated in the drawing and explained in more detail in the following description. Show it:

1 a schematic side view of a drill and / or percussion hammer,

2 a partial section of a front portion of the hammer drill 1 with a bearing carrier according to the invention.

Description of the embodiments

1 shows a schematic view of a drill and / or chisel hammer 10 as an example of a machine tool with a housing 12 , one on the housing 12 movably arranged tool holder 14 for receiving an insert tool 16 and one in the case 12 recorded, a drive unit 18 and a transmission unit 20 having drive device 22 for driving the insert tool 16 , The tool holder 14 is preferably on a front side 24 of the housing 12 rotatably arranged. At one of the front side 24 of the housing 12 opposite side of the housing 12 is in the example after 1 further a handle device 26 intended. The handle device 26 includes in the present example a device main switch 28 to a commissioning of the drill and / or chisel hammer 10 , Furthermore, the case 12 of the drill and / or chisel hammer 10 an auxiliary handle device 30 arranged, in particular arranged adjustable. The housing 12 of the drill and / or chisel hammer 10 furthermore has at least one, preferably two or more ventilation openings 32 on. Depending on an air flow direction 34 . 36 the ventilation opening acts 32 either as an air inlet opening 38 or as an air outlet opening 40 , At least however, on the case 12 an air inlet opening 38 intended.

In a transition area 42 between the case 12 and the tool holder 14 , in particular between the housing 12 and a jacket sleeve 44 of the tool holder 14 , is an additional air outlet 46 intended.

The drive unit 18 includes in the present example a motor 48 , in particular an electric motor 50 and a motor shaft not shown here. About the motor shaft is the engine 48 . 50 with the gear unit 20 operatively connected.

The gear unit 20 the drill and / or chisel hammer described here 10 has in known form a rotary drive gear and / or a striking mechanism with a percussion drive gear. In known drilling and / or chipping hammers 10 the striking mechanism is often designed as a so-called air cushion or air spring impact mechanism. As already mentioned at the beginning, airbag impact devices in many ways produce contributions to a waste heat of the drive device 22 of the drill and / or chisel hammer 10 ,

2 shows a front portion of the drill and / or chisel hammer 10 in a partial section.

The tool holder 14 points next to the jacket sleeve 44 a tool holder 52 , which is preferably made on a metallic material, in particular a steel, and at least one locking element 54 comprehensive locking device 56 on. In the tool holder 52 becomes an insertion end 58 of the insert tool 16 taken and over the locking device 56 locked.

The gear unit 20 of the drill and / or chisel hammer 10 has a work spindle 60 , preferably a hammer tube 61 as an example of a rotatable shaft 59 on. The tool holder 52 is an example here in an open end 62 the work spindle 60 . 61 inserted and preferably rotationally fixed and axially immovable with the work spindle 60 . 61 connected. In the example below 2 becomes the tool holder 52 into the tool holder 52 engaging and through the work spindle 60 . 61 thorough locking body 64 with the work spindle 60 . 61 connected.

The work spindle 60 . 61 is about a plain bearing 66 in a gearbox 68 taken up and rotatably supported relative to this. The gearbox 68 is outward from the case 12 , in particular a hammer tube hood 70 demarcated and at least partially enclosed. Here is the gearbox 68 in particular made of a metallic material, preferably of a steel. The hammer tube hood 70 is like the case 12 preferably made of a plastic. Between the work spindle 60 . 61 and the transmission housing 68 are also a felt ring 72 and a radial shaft seal 74 arranged over which the transmission housing 68 is sealed against penetrating dust.

In a transition area between tool holder 52 and the work spindle 60 . 61 is also a firing pin 76 intended. The firing pin 76 has one or more earrings 78 on, over which an interior 80 the work spindle 60 . 61 is sealed against penetrating dust.

In so far corresponds to the structure of in 1 respectively. 2 shown drill and or chisel hammer 10 a well-known series concept for drills and / or impact hammers. Much of the heat generated inside the impact mechanism - especially in the work spindle and in the tool holder - has to be dissipated by means of heat conduction via the narrow, play-bearing slide bearing 66 outwards to the gearbox 68 be dissipated. The work spindle 60 . 61 has virtually no way to dissipate waste heat through efficient, convective heat dissipation, since the work spindle 60 . 61 practically thermally isolated from the surrounding components. The same applies in a similar context, of course, for the thermally coupled tool holder 14 ,

In the after 2 According to the invention executed drill and / or chisel hammer 10 has the gearbox 68 at least one overflow groove 82 on. The overflow 82 extends along a surface direction 71 along a surface 69 of the gearbox 68 , In this case, a surface direction is understood to mean in particular a direction which is parallel to the surface 69 runs and in particular in a local coordinate system of the surface 69 follows the surface course in a spatial direction. The overflow groove 82 located in a support area of the gear housing 68 opposite the hammer tube hood 70 or the housing 12 of the hammer drill 10 , The overflow groove 82 has the task, an air mass flow 84 towards the tool holder 14 to flow. In addition to the Überstömnuten shown here 82 In addition, experts are other gas-permeable surface structures 83 known, which according to the invention can be used to produce a convective cooling of the impact mechanism. For example, surface depressions and / or lattice structures can be used according to the invention. It can also be alternatively or additionally provided that a corresponding gas-permeable surface structure 83 ' on an inner surface of the housing 12 is provided in the support area.

In a connection area 86 between the work spindle 60 . 61 and the tool holder 52 is radially outside lying a heat sink 88 on the work spindle 60 . 61 arranged, preferably non-rotatably with the work spindle 60 . 61 connected. Under a heat sink 88 In this case, in particular, an element is understood which has a large heat conduction and / or heat transfer surface and / or convection surface and / or a low heat transfer resistance. The heat sink 88 is in the execution after 2 designed as a mainly sleeve-like component. The heat sink 88 extends preferably positive and / or non-positive over the connection area 86 , The heat sink 88 is in the present example thus in particular rotationally fixed to the work spindle 60 . 61 connected. The expert is in addition to the positive and / or non-positive connection of the heat sink 88 with the work spindle 60 . 61 Other joining techniques are known which can be used alternatively or additionally according to the invention. Thus, for example, a cohesive connection can be used by soldering or welding as an alternative or complementary connection technology. Also, in the connection area 86 a thermally conductive substance, in particular a thermal compound, the heat transfer from the work spindle 60 . 61 to the heat sink 88 favorably introduced.

In a preferred embodiment, as in 2 is shown, the heat sink 88 further with the gearbox 68 jointly trained sealing labyrinth 90 on. The sealing labyrinth 90 serves for improved dust sealing of the gear housing 68 against penetrating, dust-laden air, for example, from the air mass flow 84 ,

Preferably, the heat sink 88 one or more preferably several in the air mass flow 84 protruding cooling fins 92 on. The air mass flow 84 flows over the overflow grooves 82 and the cooling fins 92 , Thereafter, the air mass flow occurs 84 over in the transition area 42 provided additional air outlet opening 46 in the area. One especially in the front area of the hammer drill 10 generated waste heat can be so over the cooling fins 92 of the heat sink 88 efficient to the air mass flow 84 be delivered.

The heat sink 88 may also have additional features over which additional functions can be displayed. For example, a sealing labyrinth 94 be provided, over which an interior 96 of the tool holder 14 is protected from penetrating dust. Furthermore, the heat sink 88 also as a carrier for sealing elements 98 be used.

In the execution after 2 is the heat sink 88 coaxial around the work spindle 60 . 61 arranged and in particular as a centrifugal disc 100 educated. This has the advantage that by a rotary movement of the work spindle 60 . 61 the sealing effect and the cooling effect of the heat sink 88 . 100 to be reinforced.

Depending on a specific embodiment of the machine tool, the person skilled in the art will be based on the features and functions of the heat sink described herein 88 adapt it according to the requirements without changing the essential advantages and effects of the invention.

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 102004058696 A1 [0004]

Claims (14)

Machine tool with a housing ( 12 ), one on the housing ( 12 ) movably arranged tool holder ( 14 ) for receiving an insert tool ( 16 ) and one in the housing ( 12 ), a drive unit ( 18 . 48 . 50 ) and a transmission unit ( 20 ) having drive device ( 22 ) for driving the insert tool ( 16 ), which generates waste heat in one operation, characterized in that the transmission unit ( 16 ) at least one heat sink ( 88 ). Machine tool according to claim 1, characterized in that the gear unit ( 20 ) an at least rotatable shaft ( 59 ), which is at least partially surrounded by the heat sink. Machine tool according to claim 2, characterized in that the heat sink ( 88 ) the at least rotatable shaft ( 59 ) encloses substantially coaxially. Machine tool according to claim 2 or 3, characterized in that the heat sink ( 88 ) at least substantially non-rotatably, preferably non-rotatably with the at least rotatable shaft ( 59 ) connected is. Machine tool according to at least one of claims 2 to 4, characterized in that the heat sink ( 88 ) as a centrifugal sheath ( 100 ) is trained. Machine tool according to at least one of the preceding claims, characterized in that the heat sink ( 88 ) at least one with cooling fins ( 92 ) has provided partial area. Machine tool according to at least one of the preceding claims, characterized in that the heat sink ( 88 ) at least one heat receiving connection area ( 86 ) having. Machine tool according to at least one of the preceding claims, characterized in that at least parts of the gear unit ( 20 ) in a transmission housing ( 68 ) are arranged, which in the housing ( 12 ) is recorded. Machine tool according to claim 8, characterized in that the transmission housing ( 68 ) at least on one surface ( 69 ) at least one in a surface direction ( 71 ) gas-permeable surface structure ( 83 ), preferably at least one overflow groove ( 82 ) in a plane direction ( 71 ) having. Machine tool according to at least one of the preceding claims, characterized in that in the housing ( 12 ) at least one air inlet opening ( 38 ) is provided, via which a cooling air flow to a removal of at least a portion of the waste heat in the housing ( 12 ) and that in a transitional area ( 42 ) between the tool holder ( 14 ) and the housing ( 12 ) at least one air outlet opening ( 46 ) is provided for the exit of at least a fraction of the cooling air flow. Machine tool according to at least one of the preceding claims, characterized in that the heat sink ( 88 ) at least via a dust-tight sealing point ( 90 . 94 ), via which a direct contact of the gear unit ( 20 ) With the cooling air flow as far as possible, preferably almost completely prevented. Machine tool according to at least one of claims 2 to 11, characterized in that the at least rotatable shaft ( 59 ) an at least rotatable work spindle ( 60 ), in particular a hammer tube ( 61 ). Machine tool according to at least one of the preceding claims, characterized in that the machine tool is a hand tool, in particular a drill and / or chisel hammer ( 10 ). Method for cooling a machine tool, in particular a handheld power tool, which has a housing in a housing ( 12 ), a drive unit ( 18 ) and a transmission unit ( 20 ) having drive device ( 22 ), which generates waste heat in one operation, wherein at least one in the housing ( 12 ) provided air inlet opening ( 38 ) a cooling air flow to a removal of at least a portion of the waste heat in the housing ( 12 ) flows, characterized in that at least a part of the cooling air flow via an on an at least rotatable shaft ( 59 ) of the transmission unit ( 20 ) arranged heat sink ( 88 ) flows.

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