KR102183219B1 - Compressing Spray Can Manufacturing Method - Google Patents

Abstract

The present invention relates to an apparatus and a method for manufacturing a blower container which allows a container transfer operation to be performed by a continuous operation. The method of the present invention comprises: a resin expanding step; a resin adhering step; a resin cutting step; a molding resin transfer step; a blower means descending step; a blower air supply step; a resin transfer step; a scrap removing step; a container transfer step; a synthetic resin cooling step; and a synthetic resin container arranging step.

Description

Blower container manufacturing apparatus and method {Compressing Spray Can Manufacturing Method}

The present invention relates to an apparatus and method for manufacturing a blower container, and in particular, the body of the container is made of synthetic resin, but by additionally installing a belt part for transferring the finished product, cooling is performed in the process of transferring the finished container by a continuous operation. It relates to an apparatus and method for manufacturing a blower container, characterized in that the container is transported.

In general, transparent or opaque packaging containers manufactured using synthetic resin are formed by pressing (press) molding by a heating type molding machine at a set temperature and pressure, but such conventional molding machines manufacture packaging containers by using a heating mold divided into upper and lower parts. Is done.

That is, the conventional molding machine advances the rolled fabric between the upper and lower divided molds, but has a molded groove in the shape of a container designed to be selectively selected on the upper or lower side between the divided molds, and the preheated or heated fabric is After forming into a packaging container designed by pressing in the shape of the forming groove, it is formed to be finished by cutting each product by the control unit.

On the other hand, in Korean Patent No. 10-0979862, such a molding machine is described in the prior art. As shown in Figs. 1 and 2 of the above patent, in the normal direct blow molding method, the cylindrical shape is melted by the extruder 121. Perisone (P), which is a resin, is extruded, and the perisone (P) is inserted in the mold tightening process of the split mold 101 divided into two parts for blow molding, and the cavity of the split mold 101 at the bottom of the mold By cutting the bottom of the molten resin with a cutting edge disposed on the bottom pinch-off portion 105 of 102 and simultaneously heat-sealing, and cutting the top of the cylindrical molten resin with a Perison cutter 122 at the top, the bottom The perison (P) of the cylindrical body is formed, and then blow air is blown into the perison (P) by an air nozzle inserted from the top of the split mold (101) to form a molded product.

In addition, registration patent No. 10-1658726 discloses a blower molding container manufacturing apparatus comprising a raw material supply hopper 100, an extruder 200, and a blow container molding unit 300, as shown in FIG. A raw material supply hopper 100 for inputting the raw material from which moisture has been removed, and a transfer screw 210 rotated by the driving motor 220 to enable the transport of the raw material input to the raw material supply hopper 100 are installed inside. The extruder 200 is made of a melting tube 240 in which the heating element 230 is installed on the outer circumferential surface to enable melting of the raw material, and the raw material to be melted and transferred by being installed on one side of the extruder 200 is extruded. Blow molding in which the parison molding extrusion die 310 for molding the parison (P) and the parison (P) molded by the parison molding extrusion die 310 are located, and pressure is applied to the inside with gas and the inside is empty It is made of a blow container molding part 300 made of a molding mold 320 for molding the container.

In a state in which the parison used in the prior art is stored in the raw material supply hopper 100, the motor 220 and the transfer screw 210 are driven and transferred to a desired position, and at this time, the heating element 230 so that the raw material can be melted. The extruder is extruded with an extruder 200 equipped with, and accordingly, a blow molding container is manufactured by driving the parison molding extrusion die 310 constituting the blow container molding unit 300 while the raw material is extruded.

However, in the related art, it is not easy to cool the container molding, so it is not possible to continuously work on the conveyor, so there is an inconvenience in that the operator has to re-mount the completed containers on the conveyor one by one.

In other words, immediately after the container is molded, the body of the container is in a hot state, and heat remains on the bottom of the container, so if it is mounted on the conveyor immediately, it will stick to the conveyor. There was an inconvenience of having to reload it.

An object of the present invention is to solve the above problems, by additionally installing a belt part for transferring the finished product so that cooling is performed in the process of transferring the finished container, so that the transfer operation of the container is performed by a continuous operation. There is this.

As a means to achieve the above object,

The present invention includes a resin expansion step of expanding and pushing the liquid molding resin by operating the molding resin expansion means; A resin adhesion step of activating the container molding unit to wrap the resin pushed out from both sides; A resin cutting step of cutting the molding resin that has been pushed out by a predetermined length by operating the molding resin cutting device; A molding resin transfer step of moving the container molding unit to transfer the molding resin to the blower working position; A blower means lowering step of moving the blower means elevating and lowering parts to lower the blower means to enter the container forming section; A blower air supply step of manufacturing a synthetic resin container by actuating the blower means to inject air into the molding resin contained in the container molding part to fill the molding resin in the mold form of the container molding part; A resin transfer step of separating the container molded part in a horizontal direction and transferring the synthetic resin container to a cutting part for scrap removal; A scrap removal step of removing scraps from the edge of the synthetic resin container by moving the scrap removal cutting unit; A synthetic resin container transferring step of moving a belt part for transferring the finished product to cool the synthetic resin container from which the scrap has been removed, while cooling; It features a synthetic resin container arrangement step in which a synthetic resin container is handed over from the belt part for transferring the finished product using a conveyor for transferring the finished product and transferred to a desired location.

In addition, the synthetic resin container transfer step of moving the finished product transfer belt unit while cooling the synthetic resin container from which the scrap has been removed is carried out so that it is moved while accelerating cooling of the bottom surface of the container by blowing air into the bottom of the container by operating the blowing means. It is characterized by further comprising a cooling step of the synthetic resin to induce.

In addition, a molding resin expansion means (10) which forms a space in a cylindrical shape to continuously supply the molding resin, and a heating means is added therein to push the molding resin to the outside and output it in a liquid state; It is installed under the molding resin expansion means, consists of a straight bar divided into two, and serves to bond and disassemble the straight bars to cut the molding resin output by the molding resin expansion means at regular intervals. The resin cutting means for molding 20 and; The expansion means elevating part installed on the upper part of the molding resin expansion means, which is made by installing an elevating motor, and lowers the molding resin expansion means when the molding resin is inflated, cuts the molding resin, and then rises. (30) and; A molding resin blower means (40) installed on a side surface of the molding resin expansion means and inducing the expansion of the molding body into a container having a desired size while gradually expanding the volume of the molding material by injecting air to the molding resin; The blower means is raised and lowered, and when the blower means is mounted, the blower means is raised or lowered by hydraulic pressure or pneumatic pressure, and when air pressure is provided, the blower means is lowered to provide air pressure to the molding resin. A blower means elevating and descending part 50; It is installed on one side of the lower side of the molding resin expansion means, but consists of a two-divided one-side closed mold, and is transferred to the left or right in a state in which the expanded resin is inserted in the vicinity of the molding resin expansion means, and then A container molding unit 60 for inducing a desired container to be generated inside by injecting air to the molding resin by a molding resin blower means; A cutting part 70 for removing scrap located on one side of the container molding part, and configured to have the same shape as the rim of the container created by the container molding part, and cutting the rim of the container to guide only the container; It is installed on one side of the cutting part for scrap removal, and consists of two belt lines and a motor that provides rotational power to the belt line, and is transferred to the side after mounting the finished container, while the bottom surface of the container is exposed to air. A belt part 80 for transferring the finished product, which serves to be transferred while being cooled; A blowing means (90) installed at a lower end of the finished product transfer belt part by a predetermined distance and blowing air into the lower part of the finished container to accelerate the cooling of the lower surface of the container and to induce it to move; A conveyor (100) for conveying finished products which is installed on the output part of the belt part for conveying the finished product, which is installed while crossing at a right angle, and conveys the container output from the belt part for conveying the finished product to a desired position; It is installed at one end of the resin expansion means for molding and comprises a pollution reduction device (2000) for treating and reducing pollution factors existing in the work space; The pollution reduction device 2000 may include an air input pipe 2100 in which air is introduced by external power in the form of a cylindrical pipe or a polygonal pipe; A pump device 2200 connected to one end of the air input pipe 2100 to transfer air by external electric power; A case (2400) for a tornado-type air circulation device through which the air input pipe is connected to an upper portion to receive air; A tornado type air circulation device (2300) installed inside the case for the tornado type air circulation device to rotate and compress the air to heat the air; An air output pipe (2500) installed on the bottom of the case for the tornado-type air circulation device to output air; A diffusion chamber 2600 in the form of a container installed below the air output pipe 2500 and allowing air that has passed through the air output pipe to spread while splashing in all directions from the inner space; A motor input tube 2700 connected to the air input tube to input external polluted air; And a final output line 2800 installed on the output side of the diffusion chamber; In the air input pipe 2100, a first structure connector 21800 is installed at a lower portion, and an assembly protrusion 2180a having both sides inclined is installed at the end of the first structure connector 2180. 1 structure 2100A; And a second structure (2100B) for connecting with the first structure; The second structure 2100B includes: a first assembly structure 2110 installed on the outermost side; A second assembly structure that is installed at a certain distance from the first assembly structure to form a space to allow the assembly protrusion to enter into the space, and to form a consolidation groove at one end so that the assembly protrusion is inserted and fixed. (2120) and; A first repelling means (2130) installed between the first coalescence structure and the second coalescence structure; The first repelling means is installed at the front end of the first repelling means, and when the consolidation protrusion of the first assembly structure enters, it retreats to press the first repelling means, and when the consolidation protrusion is inserted into the consolidation groove of the second assembly A first repelling means moving part 2150 that is advanced by repulsion of the repelling means and positioned above the coalescence protrusion; A second repelling means (2140) installed at a rear end of the first repelling means flow unit and having a repelling function; A second repelling means moving part (2160) installed outside the second repelling means and configured to drive the second repelling means while retreating back as a cylindrical structure for driving the second repelling means; It is characterized in that it comprises a second repelling means support portion (2170) installed at the rear end of the second repelling means to support the movement of the second repelling means.

In addition, the tornado-type air circulation device 2300 includes a polygonal panel-shaped upper plate 2310 in which a cylindrical pressure control cap 2311 is installed at the upper portion, and a polygonal panel shape is formed in the lower portion. It is installed between the lower plate 2320 having the discharge hole 2321 and the upper plate 2310 and the lower plate 2320, but is inserted and coupled in a spiral form from the edge of the upper plate and the lower plate coupling portion toward the center and rotates and compresses the flowing air. It is characterized by including at least two tornado panels 2330 to output.

In addition, the pressure control cap 2311 is characterized in that it is formed by further forming a plurality of air circulation holes 2312.

As described above, the present invention has an effect of additionally installing a belt part for transferring the finished product so that cooling is performed in the process of transferring the finished container so that the transfer operation of the container is performed by a continuous operation.

1 is an exploded perspective view showing a conventional aerosol container.
Figure 2 is a conceptual diagram of expansion resin for expansion using the present invention.
Figure 3 is a conceptual diagram of the operation of the blower means using the present invention.
Figure 4 is a conceptual diagram for forming a container by operating the container forming unit of the present invention.
Figure 5 is a conceptual diagram of transferring the molding container to the cutting part for scrap removal of the present invention.
6 is a conceptual diagram of removing scrap by using the cutting part for scrap removal of the present invention.
Figure 7 is a block diagram of the blower means of the present invention, a state diagram before the blower device operation.
Figure 8 is a configuration diagram of the blower means of the present invention, a state diagram after the blower device operation.
Figure 9 is a conceptual view of the starting operation of the resin expansion means for molding of the present invention.
Figure 10 is an operation diagram of the molding resin swelling by operating the molding resin expansion means of the present invention.
11 is an operation diagram of the molding resin swelling to the maximum by operating the molding resin expansion means of the present invention.
12 is an operation diagram of cutting the molding resin of the present invention with a cutting means.
13 is an operation diagram of manufacturing a molding container by supplying air to the blower means of the present invention.
14 is an operation diagram of removing scrap by using the present invention.
15 is a configuration diagram of a belt part for transferring a finished product of the present invention.
16 is a configuration diagram of a conveyor of the present invention.
Figure 17 is a conceptual diagram of the container discharge operation of the present invention.
18 is an overall configuration diagram of a tornado-type pollution reduction device of the present invention.
Figure 19 is a perspective view of the whirlwind air circulation device of the present invention.
Figure 20 is an exploded perspective view of the whirlwind air circulation device of the present invention.
Fig. 21 is a state diagram in which the whirlwind air circulation device of the present invention is inserted into a case.
22 is a cross-sectional view showing the operating concept of the whirlwind air circulation device of the present invention.
23 is a plan view showing the operating concept of the tornado air circulation device of the present invention.
24 is a conceptual diagram illustrating the operation of the diffusion chamber of the present invention.
25 is an embodiment of the first structure and the second structure combined structure of the present invention.
26 is a first operation diagram of a first structure and a second structure combination according to the present invention.
27 is a second operation diagram of the first structure and the second structure assembly of the present invention.
Figure 28 is a flow chart of the manufacturing method of the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

In addition, a preferred embodiment of the present invention to be implemented below is already provided in each system function configuration in order to efficiently describe the technical components constituting the present invention, or system functions commonly provided in the technical field to which the present invention belongs. The configuration will be omitted as much as possible, and a functional configuration that should be additionally provided for the present invention will be mainly described.

If one of ordinary skill in the art to which the present invention pertains, among the functional configurations not shown below and omitted, the functions of the components already used in the past will be easily understood, and the configurations omitted as described above. The relationship between the elements and the elements added for the present invention will also be clearly understood.

In addition, in the following embodiments, terms will be appropriately modified and used so that those of ordinary skill in the art can clearly understand the key technical features of the present invention in order to efficiently describe the core technical features of the present invention. It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are one means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. It is only.

In addition, it is to be understood that all detailed descriptions listing specific embodiments as well as principles, aspects and embodiments of the present invention are intended to include structural and functional equivalents of these matters. It should also be understood that these equivalents include not only currently known equivalents, but also equivalents to be developed in the future, that is, all devices invented to perform the same function regardless of structure.

Thus, for example, the block diagrams herein are to be understood as representing a conceptual perspective of exemplary circuits embodying the principles of the invention. Similarly, all flowcharts, state transition diagrams, pseudocodes, etc. are understood to represent various processes performed by a computer or processor, whether or not the computer or processor is clearly depicted and that can be represented substantially in a computer-readable medium. Should be.

The functions of the various elements shown in the figures, including a processor or functional block represented by a similar concept, may be provided by the use of dedicated hardware as well as hardware having the ability to execute software in association with appropriate software. When provided by a processor, the function may be provided by a single dedicated processor, a single shared processor, or a plurality of individual processors, some of which may be shared.

In addition, the explicit use of terms presented as processor, control, or similar concepts should not be interpreted exclusively by referring to hardware capable of executing software, and without limitation, digital signal processor (DSP) hardware, ROM for storing software. It should be understood to implicitly include (ROM), RAM, and non-volatile memory. Other commonly used hardware may also be included.

In the claims of this specification, components expressed as means for performing the functions described in the detailed description include all types of software including, for example, a combination of circuit elements or firmware/microcode that perform the above functions. It is intended to include all methods of performing a function to perform the function, and is combined with suitable circuitry for executing the software to perform the function. Since the invention defined by these claims is combined with the functions provided by the various enumerated means and combined with the manner required by the claims, any means capable of providing the above functions are equivalent to those conceived from this specification. It should be understood as.

The above-described objects, features, and advantages will become more apparent through the following detailed description in connection with the accompanying drawings, whereby those of ordinary skill in the technical field to which the present invention pertains can easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Before describing various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of configurations and arrangements of elements described in the following detailed description or illustrated in the drawings. The present invention can be implemented and practiced in different embodiments, and can be carried out in various ways. Also, the device or element orientation (eg "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral"), etc. are used only to simplify the description of the present invention, and related devices Or you may find that the element simply indicates or does not mean that it should have a specific orientation.

1 is an exploded perspective view showing a conventional aerosol container.

Figure 2 is a conceptual diagram of expansion resin for expansion using the present invention.

Figure 3 is a conceptual diagram of the operation of the blower means using the present invention.

Figure 4 is a conceptual diagram for forming a container by operating the container forming unit of the present invention.

Figure 5 is a conceptual diagram of transferring the molding container to the cutting part for scrap removal of the present invention.

6 is a conceptual diagram of removing scrap by using the cutting part for scrap removal of the present invention.

Figure 7 is a block diagram of the blower means of the present invention, a state diagram before the blower device operation.

Figure 8 is a configuration diagram of the blower means of the present invention, a state diagram after the blower device operation.

Figure 9 is a conceptual view of the starting operation of the resin expansion means for molding of the present invention.

Figure 10 is an operation diagram of the molding resin swelling by operating the molding resin expansion means of the present invention.

11 is an operation diagram of the molding resin swelling to the maximum by operating the molding resin expansion means of the present invention.

12 is an operation diagram of cutting the molding resin of the present invention with a cutting means.

13 is an operation diagram of manufacturing a molding container by supplying air to the blower means of the present invention.

14 is an operation diagram of removing scrap by using the present invention.

15 is a configuration diagram of a belt part for transferring a finished product of the present invention.

16 is a configuration diagram of a conveyor of the present invention.

Figure 17 is a conceptual diagram of the container discharge operation of the present invention.

18 is an overall configuration diagram of a tornado-type pollution reduction device of the present invention.

Figure 19 is a perspective view of the whirlwind air circulation device of the present invention.

Figure 20 is an exploded perspective view of the whirlwind air circulation device of the present invention.

Fig. 21 is a state diagram in which the whirlwind air circulation device of the present invention is inserted into a case.

22 is a cross-sectional view showing the operating concept of the whirlwind air circulation device of the present invention.

23 is a plan view showing the operating concept of the tornado air circulation device of the present invention.

24 is a conceptual diagram illustrating the operation of the diffusion chamber of the present invention.

25 is an embodiment of the first structure and the second structure combined structure of the present invention.

26 is a first operation diagram of a first structure and a second structure combination according to the present invention.

27 is a second operation diagram of the first structure and the second structure assembly of the present invention.

28 is a flow chart of the manufacturing method of the present invention,

The present invention includes a resin expansion step (S10) for expanding and pushing the liquid molding resin by operating the molding resin expansion means;

A resin adhesion step of activating the container molding unit to wrap the resin pushed out from both sides;

A resin cutting step (S20) of operating the molding resin cutting device to cut the molding resin that has been pushed out by a predetermined length;

A molding resin transfer step (S30) of moving the container molding unit to transfer the molding resin to the blower working position;

A blower means lowering step (S40) of moving the blower means elevating and lowering the blower means to lower the blower means to enter the container forming section;

A blower air supply step (S50) of manufacturing a synthetic resin container by operating the blower means to inject air into the molding resin contained in the container molding unit to fill the molding resin into a mold shape of the container molding part;

A resin transfer step (S60) of separating the container molded part in a horizontal direction and transferring the synthetic resin container to a cutting part for scrap removal;

A scrap removal step (S70) of removing the edge scrap of the synthetic resin container by moving the scrap removal cutting unit;

A synthetic resin container transfer step (S80) of moving the belt part for transferring the finished product to cool the synthetic resin container from which the scrap has been removed while transferring it;

A synthetic resin cooling step (S90) of inducing movement while activating the blowing means to blow air into the lower part of the container to accelerate cooling of the lower surface of the container;

It consists of a synthetic resin container placement step (S100) in which the synthetic resin container is handed over from the belt part for transferring the finished product using a conveyor for transferring the finished product and transferred to a desired position.

The container manufacturing apparatus of the present invention largely includes a molding resin expansion means 10, a molding resin cutting means 20, an expansion means elevating part 30, a molding resin blower means 40, and a blower means elevating. The steel part 50, the container forming part 60, the cutting part 70 for scrap removal, the belt part 80 for conveying the finished product, the blowing means 90, and the conveyor 100 for conveying the finished product. Wow, it consists of a finished container 200.

The molding resin expansion means 10 has a cylindrical shape and forms a space, so that the molding resin 210 is continuously supplied, and a heating means is added therein to keep the molding resin 210 in a liquid state. It plays a role of pushing out and outputting.

The molding resin cutting means 20 is installed under the molding resin expansion means, is made of a divided straight bar, and serves to bond and disassemble the straight bars to be output by the molding resin expansion means. It serves to cut the molded resin at regular intervals.

The expansion means elevating unit 30 is installed on the upper part of the molding resin expansion means, and is made by installing an elevating motor, and lowering the molding resin expansion means when the molding resin is inflated, and cutting the molding resin It plays a role of raising after making it.

The molding resin blower means 40 is installed on the side surface of the molding resin expansion means, and by injecting air to the molding resin, the volume of the molding material is gradually expanded and induces expansion into a container of a desired size.

The blower means elevating part 50 serves to elevate and lower the blower means, and the blower means is elevated and lowered by hydraulic or pneumatic pressure while the blower means is mounted, and when air pressure is provided, the blower means is lowered and formed. Induces air pressure to be provided to the resin.

The container molding part 60 is installed on one side of the lower side of the molding resin expansion means, but is made of a closed mold on one side divided into two parts, and the expanded resin is inserted into the inner side of the molding resin expansion means. Alternatively, it is transferred to the right, and then air is injected into the molding resin by means of a molding resin blower to induce a desired container to be generated inside.

The cutting part 70 for removing the scrap is located on one side of the container molding part, but is configured in the same shape as the rim of the container created by the container molding part, and the container 200 is cut by cutting the rim of the container 200. Induce only to remain.

The finished product transfer belt unit 80 is composed of two belt lines and a motor that provides rotational power to the belt line, and is transferred to the side after mounting the finished container, but the bottom surface of the container is exposed to air. It serves to be transported while cooling.

The blowing means 90 is installed at a predetermined distance at the bottom of the belt part for transferring the finished product, and induces movement while accelerating cooling of the bottom surface of the container by blowing air into the bottom of the finished container.

The finished product conveying conveyor 100 is installed on the output part of the belt part for conveying the finished product, but is installed while crossing at a right angle, and the container output from the belt part for conveying the finished product is mounted and transferred to a desired position.

Hereinafter, the assembly method of the present invention will be described.

Looking at the main components of the present invention, the resin expansion means 10 for molding, the resin cutting means 20 for molding, the expansion means elevating part 30, the resin blower means 40 for molding, and the blower means elevating. The steel part 50, the container forming part 60, the cutting part 70 for scrap removal, the belt part 80 for conveying the finished product, the blowing means 90, and the conveyor 100 for conveying the finished product. First, the molding resin is supplied to the molding resin expansion means.

That is, the resin supply network is connected to the molding resin expansion means 10, so that the resin for molding is continuously supplied to the molding resin expansion means 10, and in addition, the inside of the molding resin expansion means 10 A heating means is further included so that the resin for molding maintains a constant high heat so that expansion can be easily performed.

In addition, the molding resin cutting means 20 is installed under the molding resin expansion means 10 so that cutting is repeated when the molding resin expands to a certain length, and the molding resin expansion means 10 On one side, a molding resin blower means 40 is installed.

In addition, the expansion means for raising and lowering the molding resin expansion means 10 is located on the upper portion of the molding resin expansion means 10, and the molding resin blower means 40 is raised and lowered. The blower means for elevating and descending part 50 is located at the top of the resin blower means 40 for molding.

In addition, under the molding resin blower means 40, a container molding part consisting of two is located, and the container molding part forms a container molding space in the same shape as the container, and the molding resin is formed in the container molding space part. As is filled, a container is created.

The expansion means elevating portion 40 and the blower elevating portion 60 are made of a hydraulic motor or a pneumatic motor, and by driving a cylinder to draw in a piston, the resin expansion means 30 and the blower means 50 are elevated and lowered. Organize to make it happen.

The container molding part 70 is located at the bottom of the molding resin blower means 50 and consists of two blocks, and forms a half-seat space part forming a container in the inner side to form a complete container by left and right flow. Space is provided. Since the concept of inducing the right and left sides of the container forming part 60 is a general technique of a blower container, further description will be omitted.

In addition, a cutting part 70 for scrap removal is installed on one side of the container molding part 60 to remove scrap existing on the edge of the container molding part 60, and the cutting part 70 for scrap removal A belt part 80 for transferring the finished product is assembled on one side, and a blowing means 90 is installed at the bottom thereof, and a conveyor 100 for transferring the finished product is installed perpendicularly to one side of the belt part 80 for transferring. Done.

In addition, the resin blower means 40 for molding of the present invention is mounted horizontally on the rear side of the operating table 41 and supplied from the blower supply unit 42 provided in the front of the operating table 41 to a hollow part. It can be blown through 43, and the end of the hollow part 43 of the working table 41 is provided with an inclined surface, so that the opening and closing can be made with an opening 44 formed to be coupled to face it, but the opening 44 is inside It is connected to the guide bar 45 of the hollow part 43 in the opposite direction to the tip of the hollow part 43, and is blocked by the guide bar 45, which is elastically supported, and is inside the hollow part 43 by the opening 47 It prevents the injection of molding materials, and during blower molding and demoulding, the tip of the hollow part 43 is opened by pushing the opening 47 by the air pressure supplied from the blower supply part 42 to blow air. It has a configuration that can be used.

Hereinafter, the overall operation of the present invention will be described.

First, the molding resin expansion means 10, the molding resin cutting means 20, the expansion means elevating portion 30, the molding resin blower means 40, the blower means elevating portion 50, It consists of a container forming part 60, a cutting part 70 for scrap removal, a belt part 80 for transferring the finished product, a blowing means 90, and a conveyor 100 for transferring the finished product. A molding resin for molding a container is supplied to the resin expansion means 10, and a heating means is operated so that the molding resin can maintain a constant temperature so that the molding resin can maintain a liquid state.

In addition, when the molding resin expansion means 10 is operated, the molding resin is continuously expanded in a downward direction, and at this time, the molding resin expansion means 10 is an expansion means when the molding resin expands. By operating the elevating part 30, it moves in the downward direction.

Then, when the expansion of the molding resin is completed, the container molding part 60 is moved in the molding resin direction to be compressed from both sides, and at this time, the molding resin is cut with the molding resin cutting means 20.

When the cutting of the molding resin is completed as described above, the molding resin expansion means 10 is moved upward, and after the container molding part 60 is transferred to one side, the blower means elevating and descending part 50 operates. As the molding resin blower means 40 descends, air is supplied to the molding resin mounted on the container molding part 60 to fill the space part of the container molding part 60 with the molding resin.

And, when the molding resin is filled, the container molding part 60 is separated from each other, and then the molding resin is moved to the cutting part 70 for scrap removal, and the container in which the cutting part 70 for removing scrap is molded. To remove the scrap existing on the rim of the scrap, a belt part 80 for transferring the finished product is assembled on one side of the cutting part 70 for scrap removal to transfer the finished container from which the scrap has been removed.

At this time, the belt unit 80 for transferring the finished product has a space at the bottom, so that the lower end of the container is cooled by natural air and transferred, and a blowing means is installed at the lower end of the container to accelerate cooling. When cooling is complete, the work is completed by transferring the container to a desired position along the conveyor for transferring the finished product installed perpendicular to one side of the transfer belt part.

On the other hand, the present invention is achieved by further installing a pollution reduction device 2000 at one end of the resin expansion means for molding, the pollution reduction device protects the worker by processing the pollution factor existing in the work space. The pollution reduction device of the present invention generates constant heat by colliding with the air as it collects, and induces a certain portion of the pollutant elements present in the polluted air to be removed while the heat is generated as described above.

In other words, heat is generated as the polluted air collides with each other, which induces a certain part to be naturally removed by friction of the polluted air.

The constituent elements of the present invention are largely an air input pipe 2100, an air input pump device 2200, a tornado air circulation device 2300, a tornado air circulation device case 2400, and an air output pipe ( 2500), a diffusion chamber 2600, a motor input line 2700, and a final output line 2800.

The air input pipe 2100 is a pipe that is erected in a vertical shape and is a pipe through which air passes through the operation of the pump device 2200 for air input. The air input pipe 2100 serves to transfer air to a whirl-type air circulation device by passing air transmitted from a motor.

The air input pump device 2200 serves to pump air to the air input pipe 2100 by rotating the impeller by receiving external power. The operating range of the pump device 2200 for air input can be appropriately adjusted according to the circulation and temperature of the air, which means that when the pump device is rotated at a high speed, the circulation speed of the air increases and the temperature rises rapidly, When the operating speed is slowed down, the air circulation speed becomes slow and the air temperature rises slowly. In the present invention, the circulation speed is varied and used for the purpose of controlling the temperature of air at an optimized speed by appropriately adjusting the rotational speed of the air input pump device 2200.

The tornado-type air circulation device 2300 has a polygonal panel-shaped upper plate 2310 in which a cylindrical pressure control cap 2311 with a closed upper portion is installed thereon, and an air discharge hole ( A lower plate 2320 having 2321), and a tornado panel 2330 in two or more directions inserted between the upper plate 2310 and the lower plate 2320 and inserted and coupled in a spiral form from the edge of the upper plate and the lower plate coupling portion to the center direction. Done.

The tornado-type air circulation device 2300 installs two or more circuit-type panels 2330 so that two or more air input spaces D are generated, and the input air is mixed into one air discharge pipe 2500. The bar is induced to flow, so that the air flowing from two or more points can be collected in one place and the temperature of the air can be increased.

On the other hand, the reason for installing the pressure control cap 2311 is that overpressure occurs in the process of rotating while air is mixed, and by the pressure, it collides with the air present in the air output pipe 2500 and is pulled upward. The air pulled to the top serves to create a free space that rotates according to the flow of air.

If the pressure control cap (2311) is not installed, there will be no place for the raised air to stay when the increased pressure caused by the rotation of the air occurs, and if so, it is undesirable when the air is discharged along the air output pipe (2500). It is not possible to secure one space, causing a rumbling phenomenon.

Since the pressure control cap 2311 of the present invention secures a space for rotating the air previously existing in the air output pipe 2500 according to the overpressure generated by the rotating air, the air discharged along the air output pipe 2500 is pressure The air output space is secured under the influence of the air existing in the control cap 2311, so that it can be discharged smoothly while being continuously rotated.

That is, only when a space is secured at the point where air is discharged by the pressure control cap 2311, the air is smoothly discharged while rotating around the space. Without the pressure control cap 2311, no space is secured at the air discharge point. As a result, a rumbling phenomenon appears and air cannot be discharged at a constant rate, and then continuous heat generation cannot be achieved.

Therefore, in the present invention, pressure is generated in the pressure control cap 2311 by the air that rotates by forming the pressure control cap 2311, and accordingly, the pressure control cap 311 increases the air from the air discharge pipe 2500. The first space (A) is secured, and at the same time, the second space (B) is secured on the central axis between the tornado air circulation device and the air output pipe, so that the first space (A) and the second space are In the state that does not invade (B), the air is discharged while being rotated, so that continuous discharge is made and heat is continuously generated.

In addition, the reason for further forming a plurality of air circulation holes 2312 on the side of the pressure control cap 2311 is that the air is initially filled in the inner space of the pressure control cap, and at this time, the air drawn is pressure controlled. This is because the air space portion C existing in the cap 2311 is pushed outward to push the air outward, and the air pushed outward must be discharged to the outside. If the hole for air circulation 2312 is not formed, the pressure control cap 2311 is filled with air, so that air is not sucked in, and thus smooth air is not discharged.

Therefore, when the air circulation hole 2312 is formed on the side of the pressure control cap 2311 as in the present invention, air is drawn up from the air discharge pipe 2500 generated by the rotation and compression of the air, and Is pushed out of the air existing in the pressure control cap 2311 to the outside of the pressure control cap 2311 through the air circulation hole 2312, and discharged through the air circulation hole 2312. Air is again input through the tornado panel 2330 and discharged to the lower side through the air discharge pipe 2500.

The tornado-type air circulation device case 2400 has a rectangular parallelepiped shape and serves to close the outer shell by including the tornado-type air circulation device 2300 inside, and the air input pipe 2100 is connected through the upper panel. , It is made by connecting the air output pipe 2500 through the lower panel.

Therefore, the air transferred through the air input pipe 2100 is transferred to the case 2400 for a tornado-type air circulation device, and thereafter, the circuit-type air circulation device 2300 inserted into the case 2400 for a circuit-type air circulation device. After passing through, it is transferred through the air output pipe 2500.

The diffusion chamber 2600 has a cylindrical or polygonal shape connected to the lower end of the air output tube, and is configured such that the end of the air output tube is inserted into the body of the diffusion chamber 2600 for a predetermined length.

The reason why the diffusion chamber 2600 is inserted under the air output tube 2500 as described above is configured because the air passing through the air output tube 2500 rotates very quickly and is transferred, so that various This is to allow air to spread in the direction.

Hereinafter, the overall operation of the present invention will be described.

First, when the air input pump device is operated, air vertically rises through the air input pipe 2100 disposed vertically. The vertically raised air flows to the inside of the circuit-type air circulation device case 2400 after the air is moved to the upper part of the circuit-type air circulation device case 2400 along the inner periphery of the air input pipe 2100.

On the other hand, the air flowing into the circuit-type air circulation device case 2400 is inserted into the circuit-type panel 2330 of the tornado-type air circulation device 2300, and the circuit-type air circulation device 2300 is a top plate 2310 ) And the lower panel 2320 and the tornado panel 2330, so the air is closed by the upper panel 2310 and the lower panel 2320, so that the air is between the upper panel 2310 and the lower panel 2320. It flows while being compressed and rotated while passing through, and then flows through the pressure control cap 2311 and the air output pipe 2500. At this time, a plurality of tornado panels 2330 are installed between the upper plate 2310 and the lower plate 2320. Therefore, when air is compressed and rotated and discharged, heat rises in the process of mixing with each other.

At this time, the pressure control cap 2311 formed on the upper plate serves to adjust the pressure according to the air flow. When the compressed air passes through the tornado panel 2330, the pressure inside the tornado air circulation device 2300 When a change occurs, a low pressure is formed in the pressure control cap 2311 so that the air in the air output pipe is sucked up so that the air pressure is properly adjusted, and the air that is rotated and compressed accordingly is discharged smoothly at a constant speed. .

In addition, since the air circulation hole 2312 is formed on the side of the pressure control cap 2311, the air raised by the low pressure pushes the air present in the inner space of the pressure control cap 2311 outward. Is output to the outside along the air circulation hole 2312, and the output air is input to the tornado panel 2320 again, thereby performing a continuous circulation process.

As a result, the present invention installs a tornado-type air circulation device 2300 inside the case 2400 for a tornado-type air circulation device, but is compressed and rotated while air flows between a plurality of tornado-type panels 2330, and compressed air Heat is generated by being combined with each other, and heat is again generated in the diffusion chamber 2600 after passing through the air output pipe 2500, thereby providing a pollution reduction device having a simple structure and maximizing efficiency.

On the other hand, the air input pipe can be divided into a double-divided assembly type bar, including the first structure (2100A) and the second structure (2100B), the first structure (2100A), the first structure connector ( It comprises 2180 and the protrusion 2180a for coalescence.

The second structure 2100B combined with the first structure 2100A includes a first uniting structure 2110, a second uniting structure 2120, a first repelling means 2130, and a second repelling It consists of a means 2140, a first repulsion means flow part 2150, a second repulsion means flow part 2160, and a second repulsion means support part 2170.

In addition, the second assembly structure 2120 includes an assembly groove 2120a, and the second repulsion means flow portion 2160 is formed by integrally forming a second repulsion means operation piece 2160a. In addition, a second repelling means support portion 2170 is formed at the rear end of the second structure 2100B. The second repelling means flowing portion 2160 has irregularities formed on the rim surface to facilitate hand gripping.

In other words, as an embodiment of combining the first structure 2100A and the second structure 2100B of the present invention, it is possible to combine naturally by one-touch, and it is not easily separated during use, and the operation of pulling by hand as necessary is possible. It is configured so that separation can only be possible.

In other words, in the coalescence structure of the present invention, it is possible to easily combine the first structure 2100A and the second structure 2100B by one-touch, and once merged, the coalescence is not easily released so that there is no separation during use, and also maintained. When separating for maintenance, since the uneven surface is separated by pulling the surface by hand, the first structure 2100A and the second structure 2100B can be separated more easily.

Hereinafter, the constituent elements of the present invention will be described in more detail.

The housing of the first structure 2100A has a cylindrical shape, and a first structure connector 2180 is installed as a means for combining with the second structure 2100B, and both ends of the first structure connector 2180 This inclined coalescence protrusion 2180a is formed.

In the second structure 2100B, a first assembly structure 2110 is installed on the outermost side, and a second assembly structure 2120 is installed below it.

A space portion is formed between the first assembly structure 2110 and the second assembly structure 2120, so that the first structure connector 2110 of the first structure 2100A is inserted into the space portion.

In addition, the first repelling means 2130 and the first repelling means flowing part 2150 are installed for one-touch coalescence, and the first repelling means flowing part 2150 is installed inside the first repulsive structure 2110 It is supported by the stepped step 2110a, and the first repelling means 2130 is located at the rear end of the first repelling means moving part 2150.

Hereinafter, the operation of the present invention will be described.

When the first structure connector 2180 of the first structure 2100B enters between the first structure for combining 2110 and the second structure for combining 2120, the first repelling means moving part 2150 is attached to the combining pin. The contact surface is pushed back, and then the first repelling means flow unit 2150 retreats while compressing the first repelling means 2130.

Thereafter, when the first repelling means flow unit 2150 is retracted by a predetermined distance, the coalescence protrusion 2180a of the first structure connection body 2180 is inserted into the coalescence groove 2120a of the second coalescence structure 2120. .

Then, the compression of the first repelling means flow unit 2150 is released and is placed back in place by the repulsive force of the first repelling means 2130, and accordingly, the first repelling means flow unit 2150 is used for combining the first structure 2100A. The first structure 2100A and the second structure 2100B are prevented from being easily separated by pressing the protrusion 2180a.

That is, looking at the process of combining the first structure 2100A and the second structure 2100B, inserting the first structure connector 2180 of the first structure 2100A into the second structure 2100B is used for the first combination. While entering the gap between the structure 2110 and the second assembly structure 2120, the first repulsive means moving part 2150 is pushed back and retracted, and the first repelling means according to the retreat of the first repelling means moving part 2150 (2130) is compressed, and after that, when the coalescence protrusion 2180a is inserted into the coalescence groove 2120a of the second coalescence structure 2120, the first reaction means moving part 2150 is in its original position and the first reaction means The moving part 2150 presses the upper portion of the coalescence protrusion 2180a so that the first structure 2100A and the second structure 2100B are strongly merged, so that they are not easily separated.

Consequently, it can be seen that when the present invention is used, the first structure 2100A and the second structure 2100B are merged with one touch.

Meanwhile, a process of separating the first structure 2100A and the second structure 2100B will be described as follows.

First, the second repelling means moving part 2160 is gripped by hand and retreated. At this time, the second repelling means flowing portion 2160 is formed with irregularities to facilitate hand gripping.

Then, the second repelling means operating piece (2160a) is retracted and the second repelling means (2140) is compressed, and at the same time, the first uniting structure (2110) combined with the second repelling means moving portion (2160) is retracted. Is done. Accordingly, the first repelling means flowing portion 2160 supported by the stepped step 2110a of the first uniting structure 2110 retreats and deviates from the uniting protrusion 2180a of the first structure 2100A.

Then, the protrusion 2180a for incorporation of the first structure 2100A can be naturally separated from the second structure 2100B.

At this time, since the union protrusion 2180a forms an inclined surface, and the union groove 2120a also forms an inclined surface, it can be separated naturally.

And, after separating the first structure 2100A and the second structure 2100B, the second repelling means operating piece 2160a and the first repelling member 2140 are repelled by the second repelling means 2140 of the second structure 2100B. The assembly structure 2110 is in its original position, so that the first structure 2100A and the second structure 2100B can be combined with one touch.

In the end, if the present invention is used, it is possible to combine the first structure 2100A and the second structure 2100B with one touch without a separate pre-operation. Accordingly, when manufacturing various three-dimensional structures, very various types of structures can be produced. It becomes possible.

10: resin expansion means for molding
20: resin cutting means for molding
30: expansion means elevating part
40: resin blower means for molding
50: blower means elevating part
60: container molding unit
70: cutting part for scrap removal
80: belt part for transferring the finished product
90: ventilation means
100: conveyor for transferring finished products

Claims (5)

delete delete Molding resin expansion means (10) which forms a space in a cylindrical shape to continuously supply the molding resin, and a heating means is added therein to push the molding resin to the outside while maintaining it in a liquid state to output;
It is installed under the molding resin expansion means, consists of a straight bar divided into two, and serves to bond and disassemble the straight bars to cut the molding resin output by the molding resin expansion means at regular intervals. The resin cutting means for molding 20 and;
The expansion means elevating part installed on the upper part of the molding resin expansion means, which is made by installing an elevating motor, and lowers the molding resin expansion means when the molding resin is inflated, cuts the molding resin, and then rises. (30) and;
A molding resin blower means (40) installed on a side surface of the molding resin expansion means and inducing the expansion of the molding body into a container having a desired size while gradually expanding the volume of the molding material by injecting air to the molding resin;
The blower means is raised and lowered, and when the blower means is mounted, the blower means is raised or lowered by hydraulic pressure or pneumatic pressure, and when air pressure is provided, the blower means is lowered to provide air pressure to the molding resin. A blower means elevating and descending part 50;
It is installed on one side of the lower side of the molding resin expansion means, but consists of a two-divided one-side closed mold, and is transferred to the left or right in a state in which the expanded resin is inserted in the vicinity of the molding resin expansion means, and then A container molding unit 60 for inducing a desired container to be generated inside by injecting air to the molding resin by a molding resin blower means;
A cutting part 70 for removing scrap located on one side of the container molding part, and configured to have the same shape as the rim of the container created by the container molding part, and cutting the rim of the container to guide only the container;
It is installed on one side of the cutting part for scrap removal, and consists of two belt lines and a motor that provides rotational power to the belt line, and is transported to the side after mounting the container, while cooling while the bottom surface of the container is exposed to air A belt part 80 for transferring the finished product, which serves to be;
A blowing means (90) installed at a lower end of the finished product transfer belt part by a predetermined distance and blowing air into the lower part of the finished container to accelerate the cooling of the lower surface of the container and to induce it to move;
A conveyor (100) for conveying finished products which is installed on the output part of the belt part for conveying the finished product, which is installed while crossing at a right angle, and conveys the container output from the belt part for conveying the finished product to a desired position;
It is installed at one end of the resin expansion means for molding and comprises a pollution reduction device (2000) for treating and reducing pollution factors existing in the work space;
The pollution reduction device 2000,
An air input pipe 2100 through which air is introduced by external power in the form of a cylindrical pipe or a polygonal tubular pipe;
A pump device 2200 connected to one end of the air input pipe 2100 to transfer air by external electric power;
A case (2400) for a tornado-type air circulation device through which the air input pipe is connected to an upper portion to receive air;
A tornado type air circulation device (2300) installed inside the case for the tornado type air circulation device to rotate and compress the air to heat the air;
An air output pipe (2500) installed on the bottom of the case for the tornado-type air circulation device to output air;
A diffusion chamber 2600 in the form of a container installed below the air output pipe 2500 and allowing air that has passed through the air output pipe to spread while splashing in all directions from the inner space;
A motor input tube 2700 connected to the air input tube to input external polluted air;
And a final output line 2800 installed on the output side of the diffusion chamber;

In the air input pipe 2100, a first structure connector 21800 is installed at a lower portion, and an assembly protrusion 2180a having both sides inclined is installed at the end of the first structure connector 2180. 1 structure 2100A; And a second structure (2100B) for connecting with the first structure;
The second structure 2100B,
A first assembly structure 2110 installed on the outermost side;
A second assembly structure that is installed at a certain distance from the first assembly structure to form a space to allow the assembly protrusion to enter into the space, and to form a consolidation groove at one end so that the assembly protrusion is inserted and fixed. (2120) and;
A first repelling means (2130) installed between the first coalescence structure and the second coalescence structure;
When the first repelling means is installed at the front end of the first repelling means, when the assembly protrusion of the first assembly structure enters, it retreats and presses the first repelling means. A first repelling means moving part 2150 that is advanced by repulsion of the repelling means and positioned above the coalescence protrusion;
A second repelling means (2140) installed at a rear end of the first repelling means flow unit and having a repelling function;
A second repelling means moving part (2160) installed outside the second repelling means and configured to drive the second repelling means while retreating back as a cylindrical structure for driving the second repelling means;
And a second repelling means support part (2170) installed at a rear end of the second repelling means to support movement of the second repelling means. The method of claim 3,
The tornado-type air circulation device 2300,
The upper plate 2310 in the shape of a polygonal panel in which the pressure control cap 2311 in the shape of a cylinder whose upper part is closed is installed on the upper part, and the lower plate 2320 having an air discharge hole 2321 in the lower part, It is installed between the upper plate 2310 and the lower plate 2320, but is inserted and coupled in a spiral shape from the edge of the upper plate and the lower plate coupling portion toward the center, and includes at least two tornado panels 2330 that rotate and compress flowing air to output Blower container manufacturing apparatus, characterized in that made by. The method of claim 4,
On the side of the pressure control cap 2311,
Blower container manufacturing apparatus, characterized in that formed by further forming a plurality of air circulation holes (2312).

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