KR20230001877U - Screw-type chip feeder - Google Patents

Abstract

The present invention provides a screw-type chip transfer device, comprising: a main body with an open upper surface, and a housing including a pair of extension parts extending on both sides at a predetermined angle from the upper surface of the main body; A rotary drive part formed at the front end of the main body, a disk- or ring-shaped support part detachably installed on the rotary drive part, and a screw part extending from the support part and installed inside the main body along the longitudinal direction of the housing. A screw unit comprising; A cutting oil discharge unit perforated on a side of the rear end of the main body to discharge cutting oil to the outside; and a cover unit that blocks the upper surface of the rear end of the housing. As a result, the problem of chips accumulating or getting caught in the main discharge part can be prevented through the main discharge part disposed on the side of the housing, and the screw part can scrape and remove chips caught in the main discharge part. In addition, the screw portion is supported on the support without the support rod, thereby preventing chips from being caught between the screw portion and the support. In addition, the presence of the cover unit allows the upper side of the screw part to be stably supported, and chips can be compressed and discharged in a narrow space.

Description

Screw-type chip feeder

The present invention relates to a screw-type chip transfer device, and more specifically, to a screw-type chip transfer device to solve the problem of chips being caught within the transfer device, causing difficulty in discharging cutting oil or causing a malfunction.

The lathe is the oldest and most widely used machine tool among machine tools, and is a device that can precisely process various machine parts using metal materials. In the case of such lathes, automatic lathes are now widely used, which not only can automatically supply workpieces, but also allow multiple cutting tools to move automatically to perform various tasks step by step, making them suitable for mass production. When cutting metal materials using such an automatic lathe, the machining surface is compressed by the bite cutting into the machining surface, causing shear slip and generating a large amount of chips. At this time, the shape of the chip takes on various forms depending on the material of the workpiece and cutting conditions, and is generally transferred and discharged from the lathe to the outside using a chip transfer device.

In this way, chips generated during cutting are discharged to the outside in a mixed state with cutting oil, which is essential for cutting. At this time, the cutting oil has a recovery cycle in which it is re-absorbed into the cutting oil pump for recycling and discharged back to the machine tool, and the chips can be collected by a separate cutting chip processing device.

However, if only the chips are not collected from the mixture of cutting oil and chips, the chips may flow into the cutting oil pump for recycling cutting oil, causing a problem that causes the cutting oil pump to malfunction. In addition, commonly used chip processing devices sometimes include a filter on the upper side of the transfer device to collect only chips from the mixture. This causes chips to accumulate in the filter, clogging the filter and preventing cutting oil from passing through the filter. Depending on this, overflow problems may occur.

In addition, in the case of a screw-type chip transfer device, the conventional technology is 'Korea Intellectual Property Office Patent No. 10-1904744 Chip Transfer Screw' and 'Korea Intellectual Property Office Publication Patent No. 10-2020-0128831 Prefabricated Spiral Conveyor for Cutting Chip Transfer'. For stable placement, support bars are formed entirely or at the front end to support the screw. However, it is common for chips to get caught between the support rod and the screw, preventing the chip from being ejected, and there is a problem that such chips get caught in the transfer device and cause failure.

Korea Intellectual Property Office Patent No. 10-1904744 Korea Intellectual Property Office Public Patent No. 10-2020-0128831

The present invention was devised to solve the above problems, and its purpose is to provide a screw-type chip transfer device to solve the problem of chips being caught within the transfer device, preventing smooth discharge of cutting oil or causing malfunctions. .

The above object includes: a housing including a main body with an open upper surface, and a pair of extension parts extending on both sides at a predetermined angle from the upper surface of the main body; A rotary drive part formed at the front end of the main body, a disk- or ring-shaped support part detachably installed on the rotary drive part, and a screw part extending from the support part and installed inside the main body along the longitudinal direction of the housing. A screw unit comprising; A cutting oil discharge unit perforated on a side of the rear end of the main body to discharge cutting oil to the outside; And a cover unit that blocks the upper surface of the rear end of the housing. This is achieved by a screw-type chip transfer device characterized by including a.

Here, the cutting oil discharge unit includes a main discharge part that is perforated in the side of the rear end of the main body to discharge cutting oil to the outside, an auxiliary discharge part that is perforated in the front end of the extension part to discharge cutting oil to the outside, and the auxiliary discharge part. It is desirable to include an auxiliary cover that controls opening and closing.

As described above, according to the present invention, the main discharge portion disposed on the side of the housing can prevent the problem of chips accumulating or getting caught in the main discharge portion, and the screw portion can scrape and remove chips caught in the main discharge portion. There is an effect.

In addition, the screw portion is supported on the support without the support rod, thereby preventing chips from being caught between the screw portion and the support.

In addition, the presence of the cover unit allows the upper side of the screw part to be stably supported, and chips can be compressed and discharged in a narrow space.

1 is a top view of a chip transfer device according to the prior art;
Figure 2 is a perspective view of a chip transfer device according to an embodiment of the present invention;
Figure 3 is a top view of a chip transfer device according to an embodiment of the present invention.

Hereinafter, the technical idea of the present invention will be described in more detail using the attached drawings. The attached drawings are only an example to explain the technical idea of the present invention in more detail, so the technical idea of the present invention is not limited to the form of the attached drawings.

Figure 1 is a top view of a chip transfer device according to the prior art, Figure 2 is a perspective view of a chip transfer device according to an embodiment of the present invention, and Figure 3 is a top view of a chip transfer device according to an embodiment of the present invention.

The screw-type chip transfer device 1 according to the prior art has a structure in which a machine tool is installed on the upper surface of the transfer device 1, and chips and cutting oil discharged from the machine tool flow into the transfer device 1. At this time, there is a cutting oil discharge part 2 capable of discharging cutting oil as shown in FIG. 1 in the upper surface area of the transfer device 1 close to the machine tool, and this cutting oil discharge part 2 is not formed vertically but is formed horizontally or It is formed in a shape inclined at a certain angle. As a result, in the process of discharging only the cutting oil from the mixture of cutting oil and chips, the chips settled in the cutting oil discharge part (2) formed to be horizontal or inclined, making recovery of the chips difficult, and these chips accumulated and blocked the cutting oil discharge part (2). A problem occurred. This clogging of the cutting oil discharge unit (2) and the phenomenon in which chips that have passed through the cutting oil discharge unit (2) are collected and collected in the cutting oil recovery unit (not shown) located at the bottom of the transfer device (1) when used for a long period of time can cause damage to the machine tool. It was difficult to maintain and repair the transfer device (1) because it was impossible to clean it without detachment.

In addition, for stable placement of the screw (3), a support bar (4) is formed to support the screw (3) overall or at the front end, but chips are caught between the support bar (4) and the screw (3), preventing the chip from being ejected. This happens frequently, and there is a problem that such chip jamming causes failure of the transfer device 1.

Therefore, the technical purpose of the screw-type chip transfer device 10 according to the present invention is to solve these problems and enable smooth discharge of cutting oil.

The screw-type chip transfer device 10 according to the present invention includes a housing 100, a screw unit 200, a cutting oil discharge unit 300, and a cover unit 400, as shown in FIGS. 2 to 5. .

First, the housing 100 is connected to a machine tool for processing metal materials and is configured to provide a space for recovering and transporting chips and cutting oil discharged from the machine tool. As shown in FIG. 2, the housing 110 and the extension Includes part 120.

The main body 110 has a top surface that is open so that it can be connected to a machine tool, and provides a space within which a screw unit 200, which will be described later, can be placed. It is preferable that the main body 110 has a polygonal cross-section rather than a circular cross-section. If the cross-section of the main body 110 is circular, it has a size and shape similar to the screw unit 200, which will be described later, so that the main body 110 and the Chips may become caught between the screw units 200, interfering with the operation of the screw units 200. Accordingly, the cross-section of the main body 110 is preferably made of a polygon to form a certain space, and the bottom is most preferably made of a flat octagon, but is not limited thereto.

The extension portion 120 is a pair of components extending from the upper surface of the main body 110 to both sides at a certain angle, and has an inclined shape whose height increases as it moves away from the main body 110. Since this extension 120 is formed to be inclined in the direction toward the main body 110, chips and cutting oil flowing in from the machine tool and chips or cutting oil flowing out of the main body 110 flow back into the main body 110. It serves as a guide to achieve this.

The screw unit 200 is installed in the main body 110 and rotates to transport chips and cutting oil. As shown in FIG. 3, it includes a rotation drive unit 210, a support unit 220, a fastening unit 230, and Includes a screw portion 240.

The rotation drive unit 210 is formed at the front end of the main body 110 and is rotated. It serves to rotate the support unit 220 and the screw unit 240, which will be described later, and is preferably made of a motor. It is not limited to this.

The support portion 220 corresponds to a disk or ring-shaped configuration that is detachably installed on the rotation drive portion 210. In the conventional case, in order to couple the rotary drive unit and the screw 3, a support bar 4 is formed to support the screw 3 at the front end or as a whole as shown in FIG. 1, but this is a support bar 4 and the screw 3. There was a problem in that chips were caught in between, causing rolling and causing failure of the screw (3). Therefore, in order to solve this problem, the support part 220 of the present invention is formed in a disk or ring shape rather than a rod shape to minimize the problem of chips being caught.

In addition, in the conventional case, if the transfer device 1 is continuously used, the transfer of chips and cutting oil may not be smooth due to wear of the screw 3. In preparation for this, the support unit 220 of the present invention is a rotary drive unit 210. It is designed to be attachable and detachable.

The fastening part 230 is provided to fasten the rotation drive part 210 and the support part 220, and various fastening means can be used, but in the present invention, bolts are most suitable as the fastening part 230. In detail, the fastening part 230 is a bolt with a thread formed on the outer surface, and the rotation drive part 210 and the support part 220 each have threads so that they can be engaged with the screw thread of the fastening part 230. Therefore, the fastening part 230 is fastened to the rotation drive part 210 and the support part 220, so that the rotation drive part 210 and the support part 220 are coupled to each other. At this time, the fastening part 230 is configured to rotate and fasten in the same direction as the rotation direction of the rotary drive unit 210. This means that when the fastening part 230 is rotated and fastened in the opposite direction to the rotary drive part 210, the rotary drive unit ( This is because a problem may occur in which the fastening part 230 is released due to rotation of the fastener 210).

In this way, when the screw unit 200 is installed to be attachable to and detachable from the rotation drive unit 210 through the support part 220 and the fastening part 230, the fastening part 230 is unfastened as necessary to connect the support part 220 and The screw portion 240 can be easily replaced or repaired.

The screw part 240 extends from the support part 220 and is installed inside the main body 110 along the longitudinal direction of the housing 100, and is rotated by the rotation drive part 210 to transport chips and cutting oil. Do it. It is preferable that the support part 220 and the screw part 240 are formed as one piece so that the screw part 240 can be stably supported on the support part 220 without a separate rod-shaped support element. In addition, by supporting the screw part 240 on the polygonal main body 110, a separation space is formed between the main body 110 and the screw part 240, thereby forming a space between the main body 110 and the screw part 240. It is possible to prevent the screw unit 240 from being damaged due to chips being caught.

The cutting discharge unit 300 is configured to have a hole in the side of the main body 110 to discharge cutting oil to the outside. As shown in FIG. 2, the cutting discharge unit 300 includes a main discharge portion 310, an auxiliary discharge portion 320, and an auxiliary cover portion. Includes (330).

The main discharge portion 310 is perforated on the rear side of the side of the main body 110 and corresponds to a configuration that discharges cutting oil to the outside. In the conventional case, the cutting oil discharge part 2 for discharging cutting oil was perforated in the extension part, but this had the problem of causing clogging by chips. Accordingly, the present invention forms the main discharge portion 310 on the side of the main body 110 to prevent the problem of clogging of the main discharge portion 310 by not providing a space for chips to be seated.

In some cases, when chips are inevitably caught in the main discharge part 310, the screw part 240, which rotates in an area close to the main discharge part 310, scratches the main discharge part 310 by rotation and causes the main discharge part ( Since chips stuck in 310 can be removed, clogging by chips can be prevented compared to when the main discharge part 310 is located in the extension part 120. In addition, the main discharge part 310 is not formed on the entire side of the main body, but at the rear area where chips are discharged to the outside. This is to facilitate recovery of the discharged cutting oil and also to facilitate maintenance such as cleaning.

The auxiliary discharge part 320 is perforated at the front end of the extension part 120 to discharge cutting oil to the outside. When the amount of cutting oil flowing in is too large, it is difficult to discharge the cutting oil using only the main discharge part 310. Cutting oil is additionally discharged through the auxiliary discharge part 320. In addition, even when maintenance of the main discharge part 310 is necessary, the cutting oil can be discharged to the outside using the auxiliary discharge part 320.

The auxiliary cover part 330 is a component that controls the opening and closing of the auxiliary discharge part 320. The auxiliary cover part prevents cutting oil from being discharged to the auxiliary discharge part 320, except in special cases where the inflow amount of cutting oil is small or Close the auxiliary discharge unit 320 using (330). This is because the presence of the auxiliary discharge part 320 in the extension part 120 may cause problems such as chips being seated on the auxiliary discharge part 330 or chips being caught between the auxiliary discharge parts 320. Therefore, in normal times, the auxiliary discharge part 320 is closed using the auxiliary cover part 330, but when cutting oil needs to be quickly discharged to the outside, the auxiliary cover part 330 is opened. Here, the auxiliary cover portion 330 can be opened and closed using a hinge method or a sliding method.

The cover unit 400 is configured to block the upper surface of the rear end of the housing 100. Since a machine tool is not placed at the rear end of the housing 100 where the main discharge portion 310 is formed, a separate cover unit 400 is required. It is possible to prevent the problem of chips and cutting oil splashing to the outside. This cover unit 400 is formed in the same or similar polygon as the main body 110 and can block the upper surface of the rear end of the main body, and can be opened when necessary to provide access to the rear end of the main body 110.

At this time, due to the presence of the cover unit 400, the screw part 340 can be stably placed in place without being bent even in the absence of a support bar, and to enable this arrangement, the cover unit 400 is connected to the screw part 340. Make sure to support the upper side stably. In addition, the presence of the cover unit 400 creates a narrow space at the rear end of the main body 110, which has the advantage that chips can be compressed and discharged.

As described above, the screw-type chip transfer device according to the present invention can prevent the problem of chips being piled up or caught in the main discharge portion through the main discharge portion disposed on the side of the housing. The screw part has the effect of scraping and removing chips stuck in the discharge part. In addition, the screw portion is supported on the support without the support rod, thereby preventing chips from being caught between the screw portion and the support. In addition, the presence of the cover unit allows the upper side of the screw part to be stably supported, and chips can be compressed and discharged in a narrow space.

The present invention is not limited to the above-described embodiments, and the scope of application is diverse, and various modifications are possible without departing from the gist of the invention as claimed in the claims.

1: Transfer device
2: Cutting oil discharge part
3: screw
4: Support rod
10: Transfer device
100: housing
110: body
120: extension part
200: Screw unit
210: Rotation drive unit
220: support part
230: fastening part
240; screw part
300: Cutting oil discharge unit
310: main discharge unit
320: Auxiliary discharge unit
330: Auxiliary cover part

Claims (2)

A housing including a main body with an open upper surface and a pair of extension parts extending on both sides at a predetermined angle from the upper surface of the main body;
A rotary drive part formed at the front end of the main body, a disk- or ring-shaped support part detachably installed on the rotary drive part, and a screw part extending from the support part and installed inside the main body along the longitudinal direction of the housing. A screw unit comprising;
A cutting oil discharge unit perforated on a side of the rear end of the main body to discharge cutting oil to the outside; and
A screw-type chip transfer device comprising a cover unit that blocks the upper surface of the rear end of the housing. According to clause 1,
The cutting oil discharge unit,
It includes a main discharge part that is perforated in the side of the rear end of the main body to discharge cutting oil to the outside, an auxiliary discharge part that is perforated in the front end of the extension part to discharge cutting oil to the outside, and an auxiliary cover that controls the opening and closing of the auxiliary discharge part. A screw-type chip transfer device characterized in that.