KR101524306B1 - An Automatic manufacturing equipment for polymerizing of Pre-polymer - Google Patents

Abstract

A prepolymer automatic polymerization and production equipment according to the present invention comprises a polymerization furnace having a space for polymerizing a prepolymer, a supply means for supplying a raw material of the prepolymer to the polymerization furnace, a heating means for heating the raw material supplied to the polymerization furnace, A cooler for cooling the inside of the polymerization furnace through cooling water, a cooler for cooling the inside of the heating means by passing the cooling water through the inside of the polymerization furnace by absorbing the heat of the polymerization furnace, And a control means for controlling the operation of the polymerization furnace, the heating means, the cooling means, the cleaning means, the cooler and the atmosphere forming means and for displaying the state And an operation display means.

Description

[0001] The present invention relates to an automatic polymerization equipment for polymerizing pre-

The present invention relates to a prepolymer automatic polymerization production facility, and more particularly, to a prepolymer automatic polymerization production facility for automatically charging and stirring raw materials of a prepolymer impregnated in an orthopedic casting tape Equipment.

The present invention relates to a prepolymer automatic polymerization and production equipment capable of rapidly cooling a polymerization furnace by providing a cooling means and having a cooler for cooling the heated cooling water by absorbing the heat of the polymerization furnace to improve the cooling efficiency .

Orthopedic casts are used to prevent additional damage by maintaining proper shape while being wrapped around the body's fracture and muscle damage areas. Previously, plaster casts made of gypsum were used, but they are heavy and heavy in air and X-ray permeability Due to their low disadvantages, moisture-curable polymer casting tapes have recently been used.

In addition to these advantages, polymer casting tapes also have various researches and experiments in order to improve the X-ray filming property, shorten the curing time, reduce heat at curing, improve sweat and foreign matter dischargeability, maintain appropriate strength and elasticity, have.

Polyurethane resin is widely used as the most typical polymer used for the polymer casting tape. The technique using polyurethane is disclosed in German Patent Publication No. 2,353,212, British Patent No. 1,578,895, US Patent No. 4,376,438, 81/00671.

Since the polymer as the most important factor of the moisture-curable polymer casting tape not only has to satisfy the above-mentioned conditions but also develops various material characteristics in the polymerization process, development of a device capable of controlling various variable factors in the polymer polymerization process is required Do.

For example, Korean Patent Laid-Open No. 10-2009-0121802 discloses an apparatus for polymerizing a polymer, which is equipped with a stirring means and a heating element so that raw materials can be stirred in a polymerization furnace.

However, since the above technique is an apparatus for experiments, it is not suitable for mass production of polymers, and it is inconvenient to supply various raw materials.

In addition, since there is no means for cooling the polymerization furnace, temperature control inside the polymerization furnace is not smooth.

It is an object of the present invention to solve the above problems and provide a prepolymer automatic polymerization and production equipment capable of automatically charging and stirring raw materials of a prepolymer impregnated in an orthopedic casting tape.

It is another object of the present invention to provide a method for producing a prepolymer which is capable of rapid cooling of a polymerization furnace by providing a cooling means and having a cooler for cooling the heated cooling water by absorbing heat of the polymerization furnace, Equipment.

A prepolymer automatic polymerization and production equipment according to the present invention comprises a polymerization furnace having a space for polymerizing a prepolymer, a supply means for supplying a raw material of the prepolymer to the polymerization furnace, a heating means for heating the raw material supplied to the polymerization furnace, A cooler for cooling the inside of the polymerization furnace through cooling water, a cooler for cooling the inside of the heating means by passing the cooling water through the inside of the polymerization furnace by absorbing the heat of the polymerization furnace, And a control means for controlling the operation of the polymerization furnace, the heating means, the cooling means, the cleaning means, the cooler and the atmosphere forming means and for displaying the state And an operation display means.

The heating means, the cooling means, the cooler, and the cleaning means are independently executed sequentially.

The heating means includes a fluid storage portion for storing a fluid passing through the inside of the polymerization furnace, a heating body for heating the fluid, a heating line for allowing the fluid storage portion and the polymerization furnace to communicate with each other, And a heating pump for urging the flow of the fluid.

The polymerization reactor is provided with a discharge line for selectively allowing the inside of the polymerization reactor to communicate with the outside, a discharge pump for supplying a suction force into the polymerization furnace at one side of the discharge line, and a pre- A filter, and a container for storing the filtered prepolymer.

As described in detail above, in the prepolymer automatic polymerization and production equipment according to the present invention, the raw materials of the prepolymer impregnated in the casting tape for orthopedic surgery can be automatically charged and stirred.

Thus, there is an advantage that productivity and ease of use are improved.

In addition, since a cooler for cooling the polymerization furnace is provided and a cooler for cooling the heated cooling water by absorbing the heat of the polymerization furnace is provided, the cooling efficiency is improved and the quality of the prepolymer can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a general view showing a prepolymer automatic polymerization and production facility according to the present invention. FIG.
2 is a detailed view showing a combination state of a polymerization furnace, a heating means, and a cooling means as one component in the prepolymer automatic polymerization production equipment according to the present invention.
3 is a schematic view showing the flow direction of cooling water during operation of the cooling means, which is one of the components of the prepolymer automatic polymerization and production equipment according to the present invention.
4 is a schematic view showing a flow direction of cooling water during operation of the cooler, which is one of the components of the prepolymer automatic polymerization and production equipment according to the present invention.

Hereinafter, the construction of a prepolymer automatic polymerization and production facility (hereinafter referred to as 'production facility 100') according to the present invention will be described with reference to FIG.

FIG. 1 is a block diagram showing a prepolymer automatic polymerization / production equipment 100 according to the present invention.

Prior to this, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may appropriately define the concept of the term in order to describe its invention in the best possible way It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

As shown in these drawings, the production facility 100 is provided with a polymerization furnace 110 for receiving and polymerizing raw materials of a prepolymer therein. In the polymerization furnace 110, A polymerization space 112 which is a space is formed.

A stirrer 114 is rotatably installed at the center of the polymerization space 112. The stirrer 114 generates a rotational force at the time of power application and stirs a plurality of kinds of raw materials.

To this end, the stirrer 114 includes a stirring motor 115 for generating a rotating power, a rotating shaft 116 rotating in conjunction with the stirring motor 115, And a stirring blade (117).

The stirring vanes 117 are configured to maximize stirring efficiency.

A flow path 118 is formed at the inner edge of the polymerization furnace 110. The flow path 118 is a space for accommodating the hot water or the cooling water in the operation of the heating means 170 and the cooling means 180 to be described below and the hot water or the cooling water is passed through the flow path 118, So that it can be drained to the outside of the furnace 110.

Therefore, it is preferable that the flow path 118 is formed so as to be partitioned from the polymerization space.

The polymerization furnace 110 is provided with a lid 111 so that the polymerization space 112 can be selectively opened. In the lower part of the polymerization furnace 110, a polymerized prepolymer is discharged Line 122 is connected.

The discharge line 122 is coupled to selectively communicate with the inside of the polymerization space 112 and is a constitution of the storage means 120 for storing the polymerized prepolymer.

That is, the storage means 120 includes a discharge line 122, a discharge line 122 for selectively allowing the inside of the polymerization furnace 110 to communicate with the outside, A filter 126 for filtering the prepolymer discharged through the discharge line 122 and a container 128 for storing the filtered prepolymer.

The discharge line 122 may further include a heater 129 for maintaining the fluidity of the prepolymer flowing to the container 128.

On the left side of the polymerization furnace 110, a supply means 130 is provided. The supply means 130 is configured to supply the raw material into the polymerization space 112. The raw material may be a variety of phase materials such as a liquid phase or a powder phase and includes a storage portion 132 for storing raw materials, A supply line 134 for allowing the interior of the polymerization furnace 110 to communicate with the storage part 132 and a supply pump 136 for forcing the supply of the raw material into the polymerization furnace 110.

The raw material stored in the storage unit 132 can be supplied to the interior of the polymerization furnace 110 by the operation of the supply pump 136. The supply means 130 includes a plurality of raw materials, It is preferable to be configured such that they can be individually supplied to the inside of the apparatus.

On the right side of the polymerization furnace 110, a cleaning means 140 is provided. The cleaning means 140 is for cleaning the polymerization space 112 by spraying the cleaning water into the polymerization space 112. The cleaning means 140 includes a washing water storage portion 142 for storing the washing water, And a washing pump 146 for supplying a suction force to the washing water storage unit 142 to force the washing water to flow into the polymerization furnace 110.

Preferably, the cleaning line 144 is coupled to the upper part of the polymerization furnace 110 in a branched state, and the nozzle 148 is provided at the end of the branched cleaning line 144 to increase the cleaning power.

On the upper side of the polymerization furnace 110, an atmosphere forming means 150 is provided. The atmosphere forming means 150 includes a vacuum pump 152 and a vacuum line 154. The vacuum pump 152 is configured to remove moisture and air by forming a vacuum atmosphere in the polymerization space 112.

The atmosphere forming means 150 may further include a gas filling portion 156 for filling the polymerization space 112 with nitrogen gas.

An exhaust port 160 for exhausting a gas generated during the polymerization reaction to the outside is provided on the upper side of the polymerization furnace 110, and operation display means 101 for operation control and status display of the above configuration are provided.

A heating means 170 for heating the polymerization space 112 via hot water to the flow path 118 as described above is provided outside the polymerization furnace 110 and a heating means 170 for heating the polymerization space A cooler 190 for cooling the inside of the cooling means 180 when the cooling water inside the cooling means 180 is heated is installed.

The detailed structure of the heating means 170, the cooling means 180 and the cooler 190 will be described with reference to FIG.

FIG. 2 is a detailed view showing a combined state of the polymerization furnace 110, the heating means 170 and the cooling means 180 in the prepolymer automatic polymerization and production facility 100 according to the present invention.

As shown in the drawing, a heating means 170 is provided on the right side of the polymerization furnace 110. The heating means 170 is configured to heat the polymerization space 112 by supplying the fluid stored in the heating means 170 to the heating flow path 118. The heating means 170 includes a fluid storage portion 172 and a heating element 174 for heating the fluid, A heating line 176 for making the fluid reservoir 172 and the flow path 118 communicate with each other, and a heating pump 178 for urging the flow of the fluid.

Accordingly, when the heating pump 178 operates to forcibly transfer the fluid, the fluid stored in the fluid reservoir 172 passes through the flow path 118 along the heating line 176, (See arrows in Fig. 2). It is preferable that the heating element 174 is automatically controlled so as to properly maintain the temperature of the fluid.

The cooling unit 180 is configured to cool the polymerization reactor 110 that has undergone the polymerization reaction and includes a cooling water storage unit 182 in which cooling water is stored and a cooling water storage unit 182 in which the cooling water storage unit 182 and the oil passage 118 are communicated A cooling line 184, and a cooling pump 186 for forcing the flow of the cooling water.

The cooling water stored in the cooling water storage portion 182 flows along the cooling line 184 to the polymerization furnace 110 via the flow path 118, And then flows into the cooling water storage unit 182 again to cool the polymerization furnace 110 (see arrows in FIG. 3).

A cooler 190 is provided on the left side of the cooling unit 180. When the temperature of the cooling water stored in the cooling water storage unit 182 is high and the cooling water stored in the cooling water storage unit 182 is not suitable for cooling the polymerization furnace 110, .

To this end, the cooler 190 includes a rapid cooler 192 for rapidly cooling the cooling water, a rapid cooling line 194 for allowing the rapid cooler 192 and the cooling water storage 182 to communicate with each other, And a rapid cooling pump 196 installed at one side of the cooling pipe 194 for forcing the flow of the cooling water.

Accordingly, when the rapid cooling pump 196 operates to forcibly transfer the cooling water, the rapid cooling line 194 forms a flow path of the cooling water so that it can pass between the cooling means 180 and the cooler 190 .

Hereinafter, a process of polymerizing the prepolymer using the production facility 100 constructed as described above will be described with reference to FIGS. 1 to 4

FIG. 3 is a schematic view showing a flow direction of cooling water during operation of the cooling unit 180, which is one component of the prepolymer automatic polymerization and production equipment 100 according to the present invention. FIG. 4 is a schematic view of a prepolymer automatic polymerization and production facility 100 according to the present invention. FIG. 3 is a schematic view showing a flow direction of cooling water during operation of the cooler 190, which is a constitution in FIG.

1, the raw material stored in the storage unit 132 is introduced into the polymerization space 112 by the operation of the supply pump 136, and the operation of the supply pump 136 is stopped upon completion of the input of the raw material.

2, the heating element 174 of the heating means 170 generates heat to generate hot water. By the operation of the heating pump 178, the hot water passes through the heating line 176 and the flow path 118 And then flows back to the fluid storage unit 172 to heat the polymerization furnace 110 again.

At the same time, the stirring motor 115 generates rotational power to rotate the stirring vane 117 to stir the raw material. At this time, the atmosphere generating means 150 generates the inside of the polymerization furnace 110 in a vacuum atmosphere, And the like are filled in the polymerization furnace 110.

When the polymerization of the prepolymer is completed, the prepolymer is forcibly transferred to and stored in the container 128 by the operation of the discharge pump 124.

Thereafter, the cooling process of the polymerization furnace 110 is performed. That is, the cooling pump 186 circulates the cooling water to the flow path 118 (see the arrow in FIG. 3) to cool the polymerization furnace 110, and the cooled cooling water, which absorbs the heat of the polymerization furnace 110, And is cooled again by the action of the cooler 190 as shown by arrows in Fig.

That is, the rapid cooling pump 196 is forced to pass the cooling water stored in the cooling water storage unit 182 through the inside of the cooling water storage unit 182, and after rapid cooling, the cooling water is sent to the cooling water storage unit 182 to cool the cooling water do.

According to the above-described process, the polymerization of the prepolymer and the cooling of the polymerization furnace (110) are completed, and if necessary, the cleaning means 140 is operated to remove foreign matter by injecting washing water into the reaction space.

At this time, the lower part of the polymerization furnace 110 is opened so that foreign matter and washing water can be discharged.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

100. Polymer automatic polymerization production facility 101. Operation display means
110. Polymerization furnace 111. Lid
112. Polymerization space 114. Stirrer
115. Stirring motor 116. [
117. Stirring wing 118. Euro
120. Storage means 122. Discharge line
124. Drain pump 126. Filter
128. Container 129. Heater
130. Supply means 132. Storage
134. Feed line 136. Feed pump
140. Cleaning means 142. Cleaning water storage section
144. Cleaning line 146. Cleaning pump
150. Atmosphere providing means 152. Vacuum pump
154. Vacuum line 156. Gas filling section
160. Exhaust port 170. Heating means
172. Fluid storage 174. Heating element
176. Heating line 178. Heating pump
180. Cooling means 182. Cooling water reservoir
184. Cooling line 186. Cooling pump
190. Cooler 192. Rapid Cooler
194. Rapid cooling line 196. Rapid cooling pump

Claims (5)

A polymerization furnace comprising a polymerization space for polymerizing a moisture-curable polymer impregnated in an orthopedic casting tape, and a channel partitioned from the polymerization space to guide hot water or cooling water through the polymerization space outside,
Feeding means for feeding the raw material of the moisture-curable polymer to the polymerization space,
A heating unit for heating the fluid; a heating line for allowing the fluid storage unit to communicate with the flow path; and a control unit for controlling the flow of the heated fluid at one side of the heating line, Heating means for heating the raw material supplied to the polymerization furnace,
A cooling water line which cools the polymerization furnace and which comprises a cooling line for allowing the cooling water to communicate with the flow path and a cooling pump for forcing the flow of the cooling water,
A cooler that absorbs heat of the polymerization furnace to cool the inside of the heated cooling means by passing the cooling water through the inside thereof,
And a washing pump for supplying washing water to the inside of the polymerization furnace by supplying a suction force to the washing water storage section, thereby washing the inside of the polymerization furnace Cleaning means,
An atmosphere forming means composed of a vacuum pump for generating a suction force, a vacuum line for allowing the vacuum pump and the polymerization space to communicate with each other, and a gas filling portion for supplying an inert gas to the polymerization space,
And an operation display means for controlling operations of the polymerization furnace, the supply means, the heating means, the cooling means, the cleaning means, the cooler and the atmosphere forming means and displaying the state.
The prepolymer autopolymerization production equipment according to claim 1, wherein the heating means, the cooling means, the cooler, and the cleaning means are independently executed sequentially.
delete delete The method according to claim 2, wherein, at one side of the polymerization furnace,
A discharge line for selectively allowing the inside of the polymerization furnace to communicate with the outside,
A discharge pump for supplying a suction force into the polymerization furnace at one side of the discharge line,
A filter for filtering the moisture-curable polymer discharged through the discharge line,
Characterized in that a storage means comprising a container for storing the filtered moisture curable polymer is provided.

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