This disclosure relates to a tool extraction system rotary cutter devices for construction and mining use and, more particularly, to a system adapted to ease removal or extraction of cutting tools and tool holders.
Rotary material cutting or milling devices—such as road pavement mills, surface mining machines, or rotary cutter attachments for hydraulic excavators or the like for example—utilize replaceable cutting tools or bits to cut and remove material from a surface. Typically, the cutting tools wear out quickly and are thus replaced frequently and, in heaving cutting or milling operations, cutting tool replacement may be carried out daily. In some cutting or milling devices, the cutting tool is removably mounted in a tool holder that is itself removable mounted to a rotary drum. In such devices, the tool holder also wears out and is replaced, although typically not as frequently as the cutting tool.
Because rotary cutting or milling devices typically carry a large number of cutting tools, ease of tool and tool holder replacement can have an effect on overall efficiency of the device. Removal or extraction of spent tools and tool holder can be particularly time consuming if the removable part is bonded or cold-welded to its supporting structure as a result of repeated impacts during cutting or milling operation. Known systems for removing cutting tools, such as the system described in European Patent Office publication EP 1 045 075, rely on insertion of a wedge member into the tool holder so that the tool can be pushed from the tool holder by striking the wedge with a hammer or similar tool. Likewise, tool holders have traditionally been removable by striking a rear end of the tool holder with an extraction tool to push the tool holder form the drum or a base block mounted on the drum. More recently, however, tool holder extraction systems have been introduced that rely upon wedges acting against grooves formed in a surface of the tool holder. These systems, although effective, are subject to improvement.
For example, known wedge systems for cutting tool removal rely on a wedge member that is hammered upon by a service technician with the wedge extending generally perpendicularly from the tool holder. This arrangement requires the technician to have adequate space to access the wedge and may thus require the technician to work on the tool extraction with the tool and tool holder low to the ground to provide adequate overhead space. Known wedge systems for tool holder remover typically rely upon two separate wedges that are individually driven into extraction grooves formed in a surface of the tool holder. These independent wedges are stuck alternately by the service technician to cause the tool holder to work its way from the drum or base block. Because the wedges are loose and independent, the technician must control each wedge carefully. One solution to this problem is to provide a tool having a pair of wedge pieced fixed to together, but such a tool requires precise alignment of the grooves and the tool.
This disclosure is directed toward overcoming one or more of the problems described above.
In one exemplary aspect, an extraction tool adapted for extraction of a cutting tool holder mounted to a rotary member of a rotary cutting device is disclosed. The extraction tool comprises a tool frame. A first extraction wedge is connected with the tool frame, the first extraction wedge being adapted for engagement against a first surface of a cutting tool holder. A second extraction wedge is connected with the tool frame in a position spaced from the first extraction wedge, the second extraction wedge being adapted for engagement against a second surface of a cutting tool holder. At least one of the extraction wedges is movably connected with the tool frame.
In another exemplary aspect, a method of extracting a cutting tool holder from a rotary cutting device, comprises the steps of:
(a) simultaneously positioning first and second extraction wedges in an operable position adjacent to the cutting tool holder, each wedge in engagement with an associated surface of the cutting tool holder;
(b) manually holding the first and second extraction wedges in the operable position; and
(c) during step (b), alternately applying force to the first and second extraction wedges to extract the tool holder from the rotary member.
In another exemplary aspect, a method of extracting a cutting tool from a tool holder of a rotary cutting device is disclosed. The tool holder is adapted to receive a cutting tool at a forward end of the tool holder with a cutting tool surface disposed within the tool holder. At least one of the tool holder and the cutting tool defines a longitudinal axis. The method comprises the steps of:
(a) positioning an extraction tool adjacent the tool holder with a first end at a position forward of a cutting tool surface that is disposed within the tool holder and with a second end at a position rearward of the cutting tool surface, the second end being positioned within the tool holder and in engagement with the cutting tool surface; and
(b) applying force to the first end of the extraction tool in a direction other than perpendicular to the defined longitudinal axis to press the second end of the extraction tool against the cutting tool surface, thereby forcing the cutting tool to move in a forward direction.
Other features and aspects will be apparent from the following description and the accompanying drawings.
Reference will now be made in detail to exemplary embodiments that are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
The term “wedge” as used herein is intended to encompass both wedge shaped members as shown in the illustrated embodiment and also other members of other shapes that act as wedges due to at least one of their own shape or the shape of interacting portions of the tool holder 106 or base block 104. For example, one skilled in the art will recognize that a member having parallel sides may act as a wedge in the interacting surface of the tool holder 106 or base block 104 extend at an angle to the parallel side of the member. As illustrated in
The tool frame 148 may include a first clevis 150 and a second clevis 152 to which the first extraction wedge 144 and the second extraction wedge 146 are respectively connected. Each extraction wedge 144, 146 may include an elongate slot 154 through which a spring pin, screw, or other suitable fastener 156 extends to secure the associated extraction wedge 144, 146 to its respective clevis 150, 152. As will be discussed below, the elongate slots 154 allow the extraction wedges 144, 146 to pivot relative to the tool frame 148 and also move linearly relative to the tool frame 148. The illustrated connection arrangement is exemplary; other suitable connection arrangements that provide at least one of the pivotal or linear motion between the wedges 144, 146 and the tool frame 148 may be used.
The tool holder extractor 122 may include a handle assembly generally designated 158. The handle assembly 158 may include a shaft 160 connected by a ball joint 162 with the tool frame 148. The ball joint 162 may be conventional and includes a ball (not shown) and socket 164. The ball may be fastened to the tool frame 148 by a fastener, such as nut 166, or welding or other suitable fastening means. The shaft 160 is connected with the socket 164, and a grip 168 formed from plastic, rubber, or other suitable material may be provided on the shaft 160. The ball joint 162 permits the shaft 160 to be swivelable relative to the frame 148 both side to side and also vertically (relative to the position shown in
As best shown in
The tool holder extractor 122 may be used as described below when a tool holder 106 reaches a predetermined wear state or otherwise requires removal. The tool holder extractor 122 may be positioned manually adjacent to the tool holder 106, for example by a service technician holding the extractor 122 by the shaft 160 or the grip 168. The first and second extraction wedges 144,146 are thus substantially simultaneously positioned in an operable position in engagement with the extraction grooves 132 of the tool holder 106. The service technician may maintain the extraction wedges 144,146 in the operable position by use of the handle assembly 158. While the extraction wedges are manually held in place by the handle assembly 158, force is applied alternately to each of the extraction wedges 144,146, meaning that force is applied first to one of the extraction wedges 144,146 and then to the other of the extraction wedges 144,146 rather than simultaneously to both of the extraction wedges 144,146. This force may be applied manually by striking each extraction wedge 144, 146 with a suitable handheld tool such as a hammer. However, a suitable pneumatic, hydraulic, or other automated tool may be used to alternately apply force to each of the extraction wedges 144,146. By alternately apply forces to the extraction wedges 144, 146, the wedges will be driven deeper into the grooves 132, thus causing to the tool holder 106 to move out of the tool holder socket 130. The alternate application of force will cause side loading of the tool holder 106, thus easing breakage of any bonding or cold welding of the tool holder 106 to the socket 130. As apparent, although extraction grooves 132 formed in the tool holder 106 are illustrated, extraction grooves may also be formed in the surface of base block 104 confronting the tool holder 106. In either case, the grooves may receive the extraction wedges 144,146, which are driven deeper into the grooves to thereby force the tool holder 106 from the base block 104.
The pivotal and linear movement of the extraction wedges 144, 146 relative to the tool frame 148 permit easy alignment of the extraction wedges 144, 146 with the grooves 132 in the tool holder 106, which is particularly useful if the grooves 132 are not parallel at the time of tool holder extraction. The swivelable handle assembly 156 may be used by a service technician to hold the extraction wedges 144, 146 in an operable position but the swivel motion permits the shaft 158 or grip 166 to be moved out of the path of the tool used to strike or otherwise apply force to the extraction wedges 144, 146. The tool holder extractor 122 may thus be held in one hand by the service technician while a force-applying tool is operated by the technician's other hand. The disclosed tool holder extractor 122 permits removal of the tool holder 106 from a position entirely forward of the tool holder 106 and without requiring any access to the rear of the tool holder other than simple removal of any rear retention pin (not shown).
With reference to
To remove the cutting tool 108, the extractor 124 is held in the operable position shown in
It will be apparent to those skilled in the art that various modifications and variations can be made in the disclosed embodiments without departing from the scope of the invention. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only.
Number | Date | Country | Kind |
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04017694 | Jul 2004 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
62012 | Cornelius | Feb 1867 | A |
1626671 | Enberg | May 1927 | A |
3008361 | Henning | Nov 1961 | A |
3498677 | Morrow | Mar 1970 | A |
5095604 | Baker | Mar 1992 | A |
Number | Date | Country |
---|---|---|
32 23 761 | Dec 1983 | DE |
34 01 243 | Aug 1984 | DE |
1 045 075 | Oct 2000 | EP |
1186744 | Mar 2002 | EP |
729 796 | May 1955 | GB |
952 216 | Mar 1964 | GB |
WO 2005005119 | Jan 2005 | WO |
Number | Date | Country | |
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20060022510 A1 | Feb 2006 | US |