The present invention relates to cutting tools, especially an electric knife structure.
In order to increase the effect of the cutting tool in use, there are many electric cutting tools on the market, and most of this type of cutting tools are structured by directly connecting the cutter blade to a driving device such as a motor or a vibration unit. Although this structure can provide the direct driving force of the cutter blade, it is easy to cause the output end of the driving device to be twisted and deformed or even damaged when the cutter blade is pressed. This problem should be improved.
The present invention has been accomplished under the circumstances in view. It is the main object of the present invention to provide an electric knife that is stable in structure, easy to maintain, and can protect the driving device from damage.
In order to achieve the above object, the electric knife of the present invention comprises: a cutter blade and a handle, and the handle is internally equipped with a drive unit and a driven unit. The cutter blade is located in the driven unit. The drive unit and the driven unit are connected through a link, so that the drive unit can drive the cutter blade of the driven unit to reciprocate along an axis.
According to the electric knife of the present invention with the above structure, because the drive unit and the driven unit are pivotally connected by a link, when the cutter blade on the driven unit is under pressure, the compressed pressure or twisted force can be absorbed by the link, and will not be directly transmitted to the output shaft of the motor and cause damage to the output shaft.
Preferably, the drive unit comprises a first movable sleeve, the driven unit comprises a second movable sleeve, and the first movable sleeve and the second movable sleeve are connected with the link.
Preferably, the drive unit comprises a screw with two threads in opposite directions.
Preferably, the drive unit further comprises two rolling members, which are respectively set on one side of the two threads of the screw. The two rolling members can scroll along the corresponding threads.
The applicant first explains here that throughout the specification, including the embodiments described below and the claims in the scope of the patent application, the nouns related to directionality are based on the directions in the drawings. Secondly, in the embodiments and drawings that will be introduced below, the same element numbers represent the same or similar elements or their structural features.
Referring to
The drive unit 10 comprises a motor 110, a screw 120, a first movable sleeve 130, a first fixed sleeve 140, and two rolling members 150.
The motor 110 is located in the handle, and one end of the motor 110 has an output shaft 111.
The screw 120 is installed on the output shaft 111 of the motor and can rotate with the output shaft. The screw 120 is provided with two threads 121 in opposite directions.
The first movable sleeve 130 is set on the screw 120, and each of two opposite sides of the first movable sleeve is provided with a perforation 131.
The first fixed sleeve 140 is set outside the first movable sleeve 130. One end of the first fixed sleeve 140 is combined and fixed with the motor 110. The two sides of the first fixed sleeve 140 are provided with two long guide grooves 141 corresponding to the second perforations 131 of the first movable sleeve. The long axis of the guide grooves 141 is in the same direction as the axis of the motor output shaft 111
The two rolling members 150 are respectively set on one side of the two threads 121 of the screw, and the two rolling members 150 can roll along the corresponding threads 121. In this embodiment, the two rolling members 150 are two balls, but it is not limited to this. One side of the two rolling members 150 is attached to the threads 121 of the screw, and the other side protrudes out of the first movable sleeve 130 through the perforations 131 of the first movable sleeve. The protruding part of the two rolling members 150 will be limited in the guide grooves 141 of the first fixed sleeve.
The driven unit 20 comprises a cutter blade holder 210, a second movable sleeve 220, and a second fixed sleeve 230.
One end of the cutter blade 2 is fixed to the cutter blade holder 210.
The second movable sleeve 220 is set on the cutter blade holder 210 and is fixed in combination with the cutter blade holder 210.
The second fixed sleeve 230 is set outside the second movable sleeve 220 and fixed in the handle 1.
The drive unit 10 and the driven unit 20 are pivotally connected by a link 30, so that the second movable sleeve 220 of the driven unit can be driven by the first movable sleeve 130 of the drive unit. In this embodiment, one end of the first movable sleeve 130 of the drive unit 10 is provided with a pivot hole 132, and one end of the second movable sleeve 220 is also provided with a pivot hole 221, and the link 30 is respectively pivotally connected to the pivot hole 132 of the first movable sleeve and the pivot hole 221 of the second movable sleeve. Through this structure, the first movable sleeve 130 and the second movable sleeve 220 can be interlocked but can maintain the respective travel space of the first movable sleeve 130 and the second movable sleeve 220. In other words, the second movable sleeve 220 will not have a direct impact on the first movable sleeve 130 if it produces up, down, left, and right deflection.
With the structure of the present invention, the operation method is the same as that of general cutting tools. The user holds handle 1 and turns on the switch 3, and the output shaft 111 of the motor 110 will rotate and drive the screw 120 to rotate. The rotation of screw 120 will move the two rolling members 150 and push the first movable sleeve 130 to move. However, because the movable range of the two rolling members 150 is limited to the corresponding guide grooves 141, the first movable sleeve 130 can only move back and forth along one axis, which is the same axis as the output shaft 111 of the motor. The first movable sleeve 130 will be linked with the second movable sleeve 220 through the link 30, which will then drive the second movable sleeve 220 to move back and forth. The cutter blade holder 210 that fixes the cutter blade 2 is fixed to the second movable sleeve 220, so it will also move with the second movable sleeve 220, thereby achieving the function of reciprocating the cutter blade 2.
The advantages of the present invention are: Because the drive unit 10 and the driven unit 20 are pivotally connected by the link 30, when the cutter blade on the driven unit 20 is under pressure, the compressed pressure or twisted force can be absorbed by the link 30, and it will not be directly transmitted to the output shaft 111 of the motor and cause damage to the output shaft.
In addition, because the drive unit and the driven unit are separated in the present invention, each unit does not need to be disassembled and replaced during maintenance, and the maintenance is easier.
In addition, it should be noted that in the above embodiment, two rolling members 150 and two threads 121 are provided on the screw 120, but one rolling member 150 and one thread 121 can also be used, as shown in
In addition, in this embodiment, the cutter blade holder 210 and the second movable sleeve 220 are separated into two components because of the convenience of assembly. The cutter blade holder 210 and the second movable sleeve 220 can also be combined into a single component, that is, the cutter blade 2 can be directly fixed to the second movable sleeve 220. The second fixed sleeve 230 can also be combined with the handle 1 to become a part of the handle 1. Similarly, the first fixed sleeve can also be combined with the handle to become one.
Number | Date | Country | Kind |
---|---|---|---|
110213280 | Nov 2021 | TW | national |
Number | Name | Date | Kind |
---|---|---|---|
3315356 | Swanke et al. | Apr 1967 | A |
3337952 | Rosen | Aug 1967 | A |
3357102 | Korshak | Dec 1967 | A |
3359637 | Hansen | Dec 1967 | A |
9434016 | Zhou | Sep 2016 | B2 |
9561552 | Kocsis et al. | Feb 2017 | B2 |
20030041464 | Anders | Mar 2003 | A1 |
20090038164 | Vitantonio et al. | Feb 2009 | A1 |
Number | Date | Country | |
---|---|---|---|
20230145219 A1 | May 2023 | US |