1. Field of the Invention
The present invention relates to magnetic grinding technology and more particularly, to an ultra-low temperature magnetic polishing machine, which uses magnetically conductive grinding media to impact the workpiece and to further remove burrs from the workpiece and polish the workpiece after lowering the temperature of the workpiece.
2. Description of the Related Art
Regular grinding devices commonly use grinding media, such as aluminum oxide balls, glass balls or plastic balls to impact the workpiece, achieving the desired polishing effect. During impact between the grinding media and the workpiece, particles will be produced to pollute the surroundings. To avoid this problem, magnetic polishing machines are developed. A conventional magnetic polishing machine is known comprising a workpiece chamber and magnetically conductive stainless steel needles. During operation, the magnetically conductive stainless steel needles and the workpiece are put in the workpiece chamber, and then a motor is started up to rotate a magnetic disc that carries multiple permanent magnets. During rotation of the magnetic disc, an alternative magnetic field is induced, causing movement of the magnetically conductive stainless steel needles in the workpiece chamber, and therefore the magnetically conductive stainless steel needles are forced to impact the workpiece, thereby removing burrs from the workpiece and polishing the workpiece. The magnetically conductive stainless steel needles have different mechanical properties when compared to aluminum oxide balls or plastic balls. Therefore, a less amount of particles will be produced when polishing the workpiece.
However, the aforesaid method of using magnetically conductive stainless steel needles to impact the workpiece for removing burrs from the workpiece and polishing the workpiece is not applicable for the processing of flexible materials. When polishing a flexible workpiece, such as rubber, plastics or silicon rubber, the flexible workpiece will be elastically deformed when impacted by the magnetically conductive stainless steel needles, losing the effects of polishing.
The present invention has been accomplished under the circumstances in view. It is the main object of the present invention to provide an ultra-low temperature magnetic polishing machine, which is practical for grinding a flexible workpiece.
To achieve this and other objects of the present invention, an ultra-low temperature magnetic polishing machine comprises a housing defining therein a grinding chamber, a door hinged to the housing and controllable to open/close the grinding chamber, a motor mounted inside the housing below the grinding chamber, a magnetic disc having an N pole and a S pole set in between the grinding chamber and the motor and rotatable by the motor to cause an alternative magnetic field in the grinding chamber, a freezer having an output pipeline inserted into the grinding chamber and freezing medium deliverable through the output pipeline into the grinding chamber, a container set in the grinding chamber, and magnetically conductive grinding media put in the container.
During operation, the freezer is operated to lower the temperature of the workpiece, and then start up the motor to rotate the magnetic disc when the workpiece become brittle, forcing the magnetically conductive grinding media to impact the workpiece and to further remove burrs from the workpiece and polish the workpiece.
Other and further benefits, advantages and features of the present invention will be understood by reference to the following specification in conjunction with the accompanying drawings, in which like reference characters denote like elements of structure,
Referring to
The housing 11 defines therein a grinding chamber 111. Further, a thermal insulation material 18 is mounted inside the housing 11 around the grinding chamber 111 to decrease rates of heat transfer between the grinding chamber 111 and the outside space. It is to be understood that the thermal insulation material 18 is not essential. Therefore, the thermal insulation material 18 may be eliminated.
The door 12 is hinged to the housing 11, and controllable to open or close the grinding chamber 111.
The motor 13 is mounted inside the housing 11 below the grinding chamber 111.
The magnetic disc 14 is set in between the grinding chamber 111 and the motor 13 and rotatable by the motor 13. The magnetic disc 14 has an N pole and an S pole. During rotation of the magnetic disc 14, the N pole and the S pole causes an alternative magnetic field in the grinding chamber 111.
The freezer 15 comprises an output pipeline 151 and a freezing medium 152. The output pipeline 151 is inserted into the grinding chamber 111. The freezing medium 152 is delivered through the output pipeline 151 into the grinding chamber 111. The freezing medium 152 can be, for example, liquid nitrogen or liquid carbon dioxide. By means of delivering the freezing medium 152 into the grinding chamber 111 to absorb heat energy, the freezing medium 152 is changed into gas, rapidly lowering the temperature in the grinding chamber 111. Further, when the freezing medium 152 is changed into gas in the grinding chamber 111, the air pressure inside the grinding chamber 111 is relatively increased. Thus, the housing 11 has an exhaust port 112 located on its one lateral side in communication with the grinding chamber 111. Thus, when the freezing medium 152 is changed into gas in the grinding chamber 111, it will flows out of the grinding chamber 111 through the exhaust port 112 to the outside.
The container 16 is set in the grinding chamber 111. The container 16 according to this embodiment, the container 16 is a rectangular box. However, this is not a limitation. Alternatively, the container 16 can be a barrel. The magnetically conductive grinding media 17 are put in the container 16. According to this embodiment, the magnetically conductive grinding media 17 are stainless steel needles.
The operation of the first embodiment will now be explained hereinafter. After the user put the workpiece and the magnetically conductive grinding media 17 in the container 16, the container 16 is put in the grinding chamber 111, and then the door 12 is closed to seal the grinding chamber 111. Thereafter, operate the freezer 15 to deliver the freezing medium 152 through the output pipeline 151 into the grinding chamber 111. After the workpiece has been frozen and become brittle, start up the motor 13 to rotate the magnetic disc 14, forcing the magnetically conductive grinding media 17 to impact the workpiece and to further remove burrs from the workpiece and polish the workpiece.
For controlling the temperature inside the grinding chamber 111 precisely, a flow rate control valve 24 shall be used. The flow rate control valve 24 is mounted in the output pipeline 151 and connected with the temperature controller 22. Thus, the flow rate control valve 24 can be controlled by the temperature controller 22 to control the flow rate of the freezing medium 152 passing through the output pipeline 151.
The operation of this second embodiment is same as the aforesaid first embodiment. Therefore, no further detailed description in this regard is necessary.
Further, as shown in
Although particular embodiments of the invention have been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the invention. Accordingly, the invention is not to be limited except as by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
99219150 | Oct 2010 | TW | national |