KR20240040472A - Caterpillar for plastic model using 3D printer - Google Patents

Abstract

The present invention discloses an endless orbit for plastic models using a 3D printer, which is manufactured as a whole at once using a 3D printer, but allows the orbital unit to rotate and bend around a pin member to provide a feeling of a real product.

Description

Caterpillar for plastic model using 3D printer}

The present invention relates to an endless track for plastic models using a 3D printer. More specifically, it relates to a 3D track that is manufactured entirely at once using a 3D printer, but provides a realistic feel by allowing the track unit to rotate and bend around a pin member. This is about an endless orbit for plastic models using a printer.

In general, plastic models such as tanks, armored vehicles, trucks, and excavators are equipped with tracks on their wheels.

As can be seen in Figure 1, an example of a conventional caterpillar for a plastic model is a method of manufacturing it as a whole by stamping it entirely with rubber.

In this way, manufacturing a plastic model crawler out of rubber improves productivity, but has the disadvantage of not providing the feel of the real product. In other words, when made of rubber, the track unit and the pin are manufactured as one piece, so the track unit does not rotate around the pin, and therefore, when mounted on a wheel, the track unit sags or bends downward in the empty space between the wheels. Because it does not work, it does not provide the feeling of a real product.

In order to improve these shortcomings, another conventional method of manufacturing a crawler for a plastic model is to inject each part into plastic and then manufacture it as a prefabricated method.

In other words, in order to manufacture a crawler track for a plastic model using an injection method, each parts for a crawler track for a plastic model are injected as shown in FIG. 2 and then assembled and manufactured one by one as shown in FIG. 3 .

However, although conventional crawler tracks for plastic models manufactured through the injection method provide the feeling of a real product in which the orbital unit rotates and bends around a pin, there is a problem that it takes too long to assemble. In particular, assembling them one by one with precision not only takes too long and is difficult, but also causes fatigue when assembling small parts.

1) Republic of Korea Patent No. 10-0390374 (registration date: June 25, 2003), title of invention: “Caterrel and method of manufacturing the same” 2) Republic of Korea Patent No. 10-0492448 (Registration Date: May 23, 2005), Title of Invention: “Caterrel and its manufacturing method” 3) Republic of Korea Patent No. 10-1792670 (registration date: October 26, 2017), title of invention: “Caterrel driving device using wire rope” 4) Republic of Korea Patent No. 10-1652195 (registration date: August 23, 2016), title of invention: “Track structure for track vehicle”

The present invention was proposed to improve the above-mentioned problems. The purpose is to not only improve productivity by manufacturing the entire product at once using a 3D printer, but also to allow the orbital unit to bend while rotating around the pin member, giving the product a feeling of being like a real product. The goal is to provide an endless track for plastic models using the provided 3D printer.

The above-mentioned purpose is that the first pin and the second pin are arranged parallel to each other back and forth, both ends of the first pin and the second pin are connected to each other by a pin end connection portion to form a locking protrusion, and the first pin and the second pin are The middle part of the pin is connected through a pin mid-connection portion to form a locking protrusion, and has a plurality of pin members with a locking protrusion protruding structure on the bottom of the pin middle connecting portion, and has a square block shape, with the back corresponding to the first pin. It is composed of a plurality of orbital units having a structure in which a second pin coupling hole is formed through and a first pin coupling hole corresponding to the second pin is formed through the front, and the orbital units are located on the left and right sides based on the pin middle connection portion of the pin member. It consists of a left and right pair to be symmetrically assembled, and a plurality of pin members and orbital units are connected alternately and continuously to form an infinite orbit for a plastic model. The first pin of the pin member located in the front has a front The orbital unit located at the rear is inserted through the second pin coupling hole and movably connected to the second pin of the pin member located at the front, and the orbital unit located at the rear is inserted through the first pin coupling hole and is movably connected to the rear. The orbital unit located in is movably connected to the first pin of the pin member located at the rear through the second pin coupling hole, and the orbital unit located at the rear is also coupled to the first pin to the second pin of the pin member located at the rear. They are connected to each other alternately and continuously in a manner that allows them to be moved by being inserted through a ball, and the pin member and track unit are manufactured at once in an assembled state using a 3D printer rather than by assembling separate parts. This is achieved by an endless orbit for plastic models using a 3D printer, which is configured so that the angle can be adjusted while the orbital units rotate based on the pin member without being separated from each other.

In addition, both ends of the plastic model crawler are connected to each other through a connecting means to realize a track shape, and the connecting means includes a fixing pin and a pin coupling hole formed through the pin end connection portion and the pin middle connection portion of the pin member located at the end. When connecting both ends of the plastic model crawler, the orbital unit located at one end is inserted into the pin member located at the opposite end so that the first pin coupling hole of the orbital unit matches the pin coupling hole of the pin member, and then the first pin coupling hole of the orbital unit is aligned with the pin coupling hole of the pin member. It is characterized by inserting a fixing pin so that it penetrates the first pin coupling hole and the pin coupling hole, and then fixing it by bonding both ends of the fixing pin.

In addition, the width of the pin end connection portion is formed to be larger than the diameter of the first pin and the second pin, so that a locking protrusion is formed at both ends of the first pin and the second pin, and the pin end connection portion is formed larger than the diameter of the first pin and the second pin. It is characterized in that the width of the middle connection part is formed larger so that a locking protrusion is formed in the middle part of the first pin and the second pin.

The caterpillar for plastic models using a 3D printer according to the present invention not only improves productivity by eliminating the need for assembly because it is manufactured as a whole at once using a 3D printer, but also can be mounted on wheels because the orbital unit rotates and bends around the pin member. When the track unit sags or bends downward in the empty space between the wheels, it provides a feeling of a real product, which has the effect of improving product quality and customer satisfaction.

1 is a photograph illustrating an example of a conventional caterpillar orbit for plastic models;
Figures 2 and 3 are photographs illustrating another example of a conventional caterpillar orbit for plastic models;
Figure 4 is a perspective view showing the overall infinite orbit for a plastic model using a 3D printer according to the present invention;
Figure 5 is a perspective view showing an enlarged portion of only a portion of a caterpillar orbit for a plastic model using a 3D printer according to the present invention;
Figure 6 is a rear perspective view of Figure 5;
Figure 7 is an exploded perspective view showing the fin member and orbital unit applied to the present invention separated one by one;
Figure 8 is a cross-sectional view showing an enlarged portion of only a portion of an endless track for a plastic model using a 3D printer according to the present invention.

The present invention will be described in detail with reference to the attached drawings as follows.

Referring to FIGS. 4 to 8, the infinite orbit for plastic models using a 3D printer according to the present invention has a plurality of pin members 100 and orbital units 200 connected alternately and continuously to form an infinite orbit for plastic models. The track is constructed, and in particular, the pin member 100 and the track unit 200 are manufactured at once along the width direction using a 3D printer rather than by assembling separate parts.

First, the pin member 100 has a first pin 110 located in the front and a second pin 120 located in the back arranged parallel to each other, and both ends of the first pin 110 and the second pin 120 have locking protrusions. They are connected to each other by the pin end connecting portion 130 to form (132), and the pin middle connecting portion 140 is formed so that a stopping protrusion 142 is formed in the middle portion of the first pin 110 and the second pin 120. It has a structure connected through And, on the lower surface of the pin intermediate connection part 140, locking protrusions 150 are formed to protrude symmetrically from the front and rear, so that the pin intermediate connection part 140 can be easily caught on the wheel.

Here, when explaining the structure in which the locking protrusions 132 and 142 are formed, the width of the pin end connection portion 130 is formed larger than the diameter of the first pin 110 and the second pin 120, so that the first pin (132) (142) is formed. A locking protrusion 132 is formed at both ends of the first pin 110 and the second pin 120, and the width of the pin intermediate connection portion 140 is formed to be larger than the diameter of the first pin 110 and the second pin 120. Thus, a locking protrusion 142 is formed in the middle portion of the first pin 110 and the second pin 120. Therefore, as described later, when the orbital unit 200 is assembled to the first pin 110 or the second pin 120, one side is caught by the locking protrusion 132 of the pin end connection portion 130, and the other side is attached to the pin middle connection portion. It is supported so as not to move left or right by being caught on the locking protrusion 142 of (140).

Next, the orbital unit 200 has a rectangular block shape, with a first pin coupling hole 210 corresponding to the first pin 110 formed laterally penetrating at the back and corresponding to the second pin 120 at the front. The second pin coupling hole 220 has a structure formed through it in the lateral direction. And the middle portion of the first pin coupling hole 210 and the second pin coupling hole 220 is configured to penetrate each other through a communicating hole 230 to reduce material costs.

When these orbital units 200 are assembled with the pin member 100, they are composed of a left and right pair so that they are symmetrically assembled on the left and right sides with respect to the pin intermediate connection portion 140 of the pin member 100.

In addition, the plurality of pin members 100 and the orbital units 200 are alternately and continuously connected to each other to form an infinite orbit for the plastic model. That is, the orbital unit 200 located in the front is movably connected to the first pin 110 of the pin member 100 located in the front through the second pin coupling hole 220, and the pin member ( The orbital unit 200 located at the rear is inserted and movably connected to the second pin 120 of 100) through the first pin coupling hole 210, and the orbital unit 200 located at the rear is connected to the pin member located at the rear. It is movably connected to the first pin 110 of (100) through the second pin coupling hole 220, and the second pin 120 of the pin member 100 located at the rear is also connected to the orbital unit located at the rear. (200) is inserted through the first pin coupling hole (210) and connected to each other in a continuous and alternating manner in such a way that it is movably connected. Of course, the pin member 100 and the orbital unit 200 are manufactured at once in an assembled state using a 3D printer, rather than by assembling separate parts, so they are not separated from each other and are aligned in the orbit based on the pin member 100. The angle of the unit 200 can be adjusted as it rotates.

Meanwhile, both ends of the endless track for a plastic model using a 3D printer according to the present invention are connected to each other through a connecting means to implement a track shape.

Here, the connecting means is a fixing pin 300, as shown in FIG. 4, and a pin coupling hole 102 formed through each of the pin end connecting portion 130 and the pin intermediate connecting portion 140 of the pin member 100 located at the end. ) is composed of. That is, all pin members 100 are formed with a first pin 110 and a second pin 120, but only the pin member 100 located at the end does not have the second pin 120, and the pin end connection portion 130 ) and a pin coupling hole 102 is formed through the pin intermediate connection portion 140 at a position corresponding to the second pin.

With this configuration, when connecting both ends of a plastic model crawler, the orbital unit 200 located at one end is inserted into the pin member 100 located at the opposite end to connect the first pin coupling hole 210 of the orbital unit 200. After aligning the pin coupling hole 102 of the pin member 100, insert the fixing pin 300 so as to penetrate the first pin coupling hole 210 and the pin coupling hole 102 from one side, and then insert the fixing pin ( 300) can be fixed by gluing both ends together with a bond. Then, the orbital units 200 are rotatably connected to each other around the fixing pin 300.

In this way, if both ends of the endless track for a plastic model are connected by insertion through the fixing pin 300, the length of the endless track for a plastic model can be freely adjusted. That is, the length of the infinite orbit for the plastic model can be freely adjusted by leaving the side of the pin member 100 where the pin coupling hole 102 is formed as is and cutting and separating the orbital unit 200 on the opposite side to an unnecessary number. . Of course, when cutting the orbital unit 200 to an unnecessary number, the pin member 100 assembled on the orbital unit 200 to be cut is removed together and the first pin coupling hole ( It is natural to allow 210) to be exposed.

Of course, the connecting means according to the present invention may be applied in a manner other than the fixing pin 300 method.

Now, we will explain the installation and operating relationship of the infinite orbit for plastic models using a 3D printer configured in this way.

The present invention is manufactured at once using a 3D printer to be entirely connected to each other along the width direction of the endless track.

Therefore, in the present invention, there is no need to manufacture each part separately and then assemble them together, and it is easily mounted on the wheel in a track shape by simply connecting the two ends to each other through the connecting means 300 while mounting it so that it hangs over the wheel. .

The endless orbit for plastic models using a 3D printer equipped in this way is manufactured by connecting a plurality of orbital units 200 through the pin member 100 so that they rotate naturally based on the first pin 110 or the second pin 120. Therefore, when mounted on a wheel, the orbital unit 200 sags or bends downward in the empty space between the wheels, providing a feeling like a real product.

As described above, the present invention has been shown and described in relation to specific embodiments, but it is understood by those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who grows up will be able to understand it easily.

100: pin member 110: first pin
120: second pin 130: pin end connection
140: Pin middle connection 150: Locking protrusion
200: Orbital unit 210: First pin coupling hole
220: Second pin coupling hole 230: Communication hole
300: Connection means 310: Fixing pin
320: fixture

Claims (4)

The first pin and the second pin are arranged parallel to each other back and forth, both ends of the first pin and the second pin are connected to each other by a pin end connector to form a locking protrusion, and the middle part of the first pin and the second pin is A plurality of pin members connected through a pin intermediate connection portion to form a locking protrusion, and having a structure with a protruding locking protrusion formed on the lower surface of the pin intermediate connecting portion;
It has a rectangular block shape, and is composed of a plurality of orbital units having a structure in which a second pin coupling hole corresponding to the first pin is formed through the back and a first pin coupling hole corresponding to the second pin is formed through the front,
The orbital units are made up of a left and right pair so that they are symmetrically assembled on the left and right sides based on the pin middle connection portion of the pin member, and a plurality of pin members and orbital units are connected alternately and continuously to create an infinite orbit for plastic models. To configure it,
The orbital unit located at the front is movably connected to the first pin of the pin member located at the front through the second pin coupling hole, and the orbital unit located at the rear is coupled to the first pin at the second pin of the pin member located at the front. It is movably connected by being inserted through a ball, and the orbital unit located at the rear is movably connected by being inserted through a second pin coupling hole to the first pin of the pin member located at the rear, and the orbital unit located at the rear is movably connected to the first pin of the pin member located at the rear. In addition, the orbital units located at the rear are inserted through the first pin coupling hole and connected movably, so that they are connected alternately and continuously.
The pin member and the orbital unit are manufactured at once assembled using a 3D printer rather than by assembling separate parts, so that the angle of the orbital unit can be adjusted as the orbital unit rotates relative to the pin member without being separated from each other. A caterpillar orbit for plastic models using a 3D printer, characterized by its configuration.
According to paragraph 1,
Both ends of the endless track for the plastic model are connected to each other through a connecting means to implement a track shape,
The connecting means consists of a fixing pin and a pin coupling hole formed through the pin end connection portion and the pin middle connection portion of the pin member located at the end,
When connecting both ends of the plastic model crawler, insert the track unit located at one end into the pin member located at the opposite end so that the first pin coupling hole of the track unit matches the pin coupling hole of the pin member, and then connect the first pin from one side. A caterpillar for plastic models using a 3D printer, characterized in that it is fixed by inserting a fixing pin through the coupling hole and the pin coupling hole and then bonding both ends of the fixing pin with a bond.
According to paragraph 1,
The width of the pin end connection portion is formed to be larger than the diameters of the first and second pins, so that a locking protrusion is formed at both ends of the first and second pins, and the middle of the pin is larger than the diameters of the first and second pins. A caterpillar for a plastic model using a 3D printer, characterized in that the width of the connection part is formed larger and a locking step is formed in the middle part of the first pin and the second pin.
Multiple pin members and orbital units are connected alternately and continuously to form an infinite orbit for plastic models.
The pin member and the orbital unit are manufactured at once using a 3D printer rather than by assembling separate parts, so they are not separated from each other, but the orbital unit rotates relative to the pin member and the angle can be adjusted. Caterpillar orbit for plastic models using a 3D printer.

Images