JP2010253939A - Plastic lens manufacturing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inhibit exposure of unwanted gas to a worker and to improve working efficiency, in manufacturing a plastic lens through manufacturing procedures that accompany production of unwanted gas such as a malodorous gas. <P>SOLUTION: The plastic lens manufacturing device comprises a preparation tank 1 which prepares lens materials, a housing 18 sealing and covering at least the circumference of the tank, a second suction unit 17 which evacuates inside the housing 18, a first suction unit which evacuates gas in the preparation tank 1, a measuring instrument for checking the state of a lens material in the preparation tank 1, a control unit 14 which determines abnormality of preparation state according to the data by measured by the measuring instrument, a temperature regulation unit 16 which regulates the temperature in the preparation tank 1, an inhibitor charging unit 12a which charges a reaction inhibitor into the preparation tank 1, and a programmable logic controller 8 which controls operation of the temperature regulation unit 16 and the inhibitor charging unit 12a on the basis of the determination made by the control unit 14. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a plastic lens manufacturing apparatus suitable for use in a plastic lens material blending process.

  In the plastic lens, a lens material having a high refractive index has been developed in various ways in order to reduce the thickness and weight. For example, it has been reported that a resin obtained by introducing and polymerizing sulfur having a high polarizability can have a high refractive index of 1.7 or more.

Although a resin containing sulfur as described above can achieve a high refractive index while maintaining a relatively high Abbe number, it emits an odor component such as hydrogen sulfide at the time of molding, so that there is a problem in workability. It was.
For this reason, the following cited document 1 proposes to reduce the amount of such odor components by subjecting a polymerizable compound having sulfur to reduced pressure for a certain period of time.

Moreover, in the following cited reference 2, in a resin composition using an inorganic compound having a sulfur atom or a selenium atom, dissolved gas such as hydrogen sulfide is removed by performing a degassing treatment, and transparency as an optical material is improved. Is disclosed.
The following cited document 3 discloses a method of detecting the reaction progress by confirming the progress of degassing of the resin composition with a refractometer.

JP 2001-172388 A JP 2006-348289 A Japanese Patent Laid-Open No. 2004-137482

  As described in Patent Document 1, by introducing a degassing step after the preparation stage of the polymerizable composition or after the preparation, odor generated at the time of molding or cutting after curing can be suppressed. However, it is not limited to this time that the worker may be exposed to odor. For example, during the preparation, when the raw material is charged, it is necessary to open the preparation tank, so that the gas in the tank may leak out.

  Therefore, it is necessary to reduce the exposure time of unnecessary gas having an odor component to the worker as much as possible. Moreover, it is desirable to prevent such leakage of odorous gas from the viewpoint of the environment. Furthermore, it is important to construct a system that copes with leaks accurately and minimizes leaks in advance.

  Therefore, in view of the above problems, the present invention, when manufacturing a plastic lens by a manufacturing process accompanied by generation of unnecessary gas such as odor gas, does not cause the operator to open and close the preparation tank directly when an abnormality occurs, The purpose is to suppress diffusion.

  In order to solve the above-described problems, a plastic lens manufacturing apparatus according to the present invention includes a preparation tank for preparing a lens material, a first suction unit for exhausting gas in the preparation tank, and a state of the lens material at the time of preparation. A temperature adjusting unit that adjusts the temperature in the mixing tank, an inhibitor charging unit that inputs a reaction inhibitor into the mixing tank, and a control unit that determines an abnormality in the mixing state based on data measured by the meter, A programmable logic controller that is connected to the control unit and controls the operation of the temperature adjusting unit and the inhibitor charging unit based on the determination of the control unit, and a housing that covers at least the periphery of the preparation tank And a second suction part for sucking and exhausting the inside of the housing.

  As described above, the plastic lens manufacturing apparatus according to the present invention exhausts, that is, depressurizes, at least the inside of the casing in which the periphery of the blending tank is sealed by the suction part. Thereby, it is possible to suppress unnecessary gas generated during the preparation of the lens material from leaking to the surroundings and diffusing.

  Further, the plastic lens manufacturing apparatus according to the present invention includes a meter for confirming the state of the lens material at the time of blending, a control unit that judges blending abnormality based on the data measured by the meter, and a blend tank A temperature adjusting unit for adjusting the temperature and an inhibitor charging unit for charging the reaction inhibitor into the preparation tank are provided. Based on the determination of the blending abnormality by the control unit, the temperature adjusting unit and the inhibitor charging unit are controlled by a programmable logic controller (PLC). This eliminates the need for the operator to directly open and close the mixing tank when an abnormality occurs, thereby avoiding exposure to the generated unnecessary gas. The operator can perform the lens material preparation step more easily and without causing leakage of odorous gas.

In the plastic lens manufacturing apparatus according to the present invention, as an instrument for confirming the state of the lens material at the time of compounding, a thermometer for measuring the temperature of the lens material at the time of compounding and the rotational speed of the stirrer for stirring the lens material at the time of compounding It is preferable to provide a tachometer for measuring the.
In this way, the mixing tank is equipped with a thermometer and a stirrer tachometer, and based on the data measured by these, a command is issued from the control unit to the PLC when mixing is abnormal, and temperature adjustment and inhibitor injection can be automatically performed. This is preferable because a mixing abnormality can be monitored more reliably.
Further, if necessary, by providing a refractometer that measures the refractive index of the lens material in the preparation tank, the progress of the reaction when the lens raw material is prepared can be more reliably monitored.
Further, when a pressure gauge for measuring the pressure in the compounding tank is provided, the compounding state can be monitored by gas generated during the lens material compounding process, expansion of the lens material, or the like.

The plastic lens manufacturing apparatus according to the present invention is connected to the control unit, and when the control unit determines that the blending state is abnormal, information on the measurement data measured by the above-described meter at the time of the blending abnormality is stored over time. It is desirable to provide a display unit that always displays. Thereby, the state of the preparation material in a preparation tank can always be confirmed easily. Moreover, when the control part judges the abnormality of a mixing state, it is preferable to perform highlighting and to make the display stand out.
In this case, the display unit is installed at an arbitrary location, and for example, by connecting the display unit and the control unit by a line or the like, the operator can monitor the compounding state of the lens material even from a remote position. it can.

  It is further preferable that an alarm device is provided, and the PLC operates the alarm device based on the determination of the control unit. As a result, it is possible to immediately notify the abnormality, and it is possible to reduce the time loss until the first response.

In the plastic lens manufacturing apparatus of the present invention, it is more preferable to provide a purification tank that directly purifies the gas exhausted from the first suction part as it is.
Further, the second suction unit may be provided with a detector that detects a predetermined gas such as an exhausted odor gas. Thus, even if unnecessary odor gas or the like leaks, it can be detected in a state of being kept in the casing, and the situation where the operator is exposed to the odor gas or the like can be prevented more reliably.

  When manufacturing plastic lenses through a manufacturing process that involves the generation of odorous gases and other unwanted gases, the operator does not directly open and close the compounding tank when an abnormality occurs, preventing unnecessary gas from leaking and spreading around be able to.

1 is a schematic perspective view of a plastic lens manufacturing apparatus according to an embodiment of the present invention. It is explanatory drawing showing the window provided in the housing | casing in the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention. It is a schematic perspective view explaining the housing | casing which seals the preparation tank of the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention. It is a block diagram showing the structure of the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention. It is a flowchart showing the process of preparing the material of a plastic lens with the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention. It is a flowchart showing the reaction process which mixes the material of a plastic lens with the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention. It is a flowchart showing the deaeration process which mixes the material of a plastic lens with the manufacturing apparatus of the plastic lens which concerns on embodiment of this invention.

The plastic lens manufacturing apparatus and its system according to embodiments of the present invention will be described below, but the present invention is not limited to the following examples. The description will be made in the following order.
1. 1. Configuration of plastic lens manufacturing apparatus Control procedure of plastic lens manufacturing apparatus (1) Flow chart of blending process (2) Flow chart of control procedure in each process a. Flow chart of reaction process b. Flow chart of deaeration process

1. Embodiment of Plastic Lens Manufacturing Apparatus (1) Configuration of Plastic Lens Manufacturing Apparatus FIG. 1 is a schematic perspective view of a plastic lens manufacturing apparatus 100 according to the present embodiment. The plastic lens manufacturing apparatus 100 according to the present embodiment includes a refractometer 2 that measures the refractive index of the material in the blending tank 1 that blends the lens material, and a stirrer that stirs the lens material in the blending tank 1. A tachometer 3 for measuring the number of revolutions is provided. The thermometer 4 that measures the temperature of the lens material in the blending tank 1, the temperature adjusting unit 16 that adjusts the temperature in the blending tank 1, and the pressure gauge 5 that measures the pressure in the blending tank 1. These devices are arranged inside a sealed casing 18. The housing 18 need not have transparency, but may be composed of a housing and a transparent panel such as glass. In particular, it is preferable that the casing and the panel unit are made of a material having durability against the generated gas that may leak. In FIG. 1, the outline of the housing 18 is indicated by a two-dot chain line in order to clearly show the configuration inside the housing 18.
The refractometer 2, the tachometer 3, the thermometer 4 and the pressure gauge 5 may be of any type as long as the accuracy necessary for determining the state of the blending process is obtained. In particular, the refractometer 2 may be a so-called in-line refractometer that directly measures the refractive index in the tank, instead of a type in which the material is taken out and measured.

Further, the housing 18 is provided with a first suction part 7 for degassing the preparation tank 1 and a septic tank 10 for purifying unnecessary gas such as odor gas sucked by the first suction part 7. . The casing 18 is connected to a second suction unit 17 that sucks and exhausts the interior of the casing 18.
Here, the exhaust unit 11 that exhausts the gas purified by the septic tank 10 is provided outside the housing 18, for example.

  In addition, the plastic lens manufacturing apparatus 100 according to the present embodiment includes an alarm device 6 that sounds an alarm when the preparation state in the preparation tank 1 is abnormal, and an inhibitor input device 12a that inputs a reaction inhibitor when the preparation is abnormal. And a cooling water input part 12b for directly supplying the cooling water into the tank. And the display part 13 which displays the measurement data of the refractometer 2, the tachometer 3, the thermometer 4, and the pressure gauge 5, and the control part 14 which judges the preparation state based on the said data, for example, PC (Personal Computer) And a PLC 8 for controlling the handling when an abnormality occurs. Note that the control unit 14 is not limited to a PC, and may be any device that can output a PLC8 signal by determining control contents from a measurement value. A measurement control device or the like having such a function may be used. Good.

As shown in FIG. 1, the casing 18 is provided with a window 20 that can be opened and closed. When a direct operation such as material input or device confirmation is required, this is opened and the operation is performed. .
The window 20 may be provided with an opening / closing door 20a so as to be openable to the outside air. Moreover, as shown in a schematic perspective view in FIG. 2, an insertion hole 21 into which an operator's hand is inserted and an airtight glove part 22 connected to the insertion hole 21 may be provided. Thus, while maintaining the airtightness in the housing 18, it is possible to perform operations such as material input and device confirmation, and it is possible to more reliably prevent exposure of odor gas and the like to the operator.

  Moreover, as shown in FIG. 3, you may equip the mixing tank 1 with the housing | casing 19 of the shape which covers the mixing tank 1 so that this may be sealed airtight. In this case, leakage of odor gas or the like can be more reliably suppressed.

  In addition, when the odor gas is a gas heavier than air, for example, hydrogen sulfide, the leaked gas tends to accumulate below. Therefore, when the second suction part 17 is connected to the lower part of the housing 18, for example, near the floor, as shown in FIG. 1, such a heavier gas than air can be sucked efficiently.

FIG. 4 is a block diagram showing the configuration of the plastic lens manufacturing apparatus 100 according to the present embodiment. A refractometer 2 is directly attached to the blending tank 1, and the refractive index of the lens material at the time of blending is measured, and the measured data is sent to the control unit 14.
Moreover, the stirrer 15 which stirs the lens material in the blending tank 1 rotates at a constant torque and stirs the lens material being blended. The stirrer 15 is connected to the tachometer 3 and sends the measured number of rotations to the control unit 14. The control unit 14 determines the viscosity of the lens material from this rotational speed.

The thermometer 4 measures the temperature of the lens material in the preparation tank 1 with, for example, a thermocouple, and the measurement data is sent to the control unit 14. The temperature adjustment unit 16 performs temperature control by an input signal from the PLC 8.
The pressure gauge 5 measures changes in the gas pressure in the preparation tank 1 due to the expansion and contraction of the gas and lens material generated by the preparation abnormality, and the data is sent to the control unit 14. Each data from the refractometer 2, the tachometer 3, the thermometer 4 and the pressure gauge 5 is constantly displayed on-line on the display unit 13 through the control unit 14 over time. For this reason, by installing the display unit 13 in an appropriate position, the operator can monitor the lens material preparation state from a remote position.
Moreover, when the control part 14 judges the abnormality of a mixing state, it is preferable to perform a highlight display. For example, the display color of the measurement data determined to be abnormal may be changed, or may be displayed in various other modes as appropriate, such as blinking display or enlarged display. In addition to emphasizing measurement data, the entire screen may be emphasized, or emphasis may be performed by symbol display indicating abnormality. At this time, in addition to the measurement data displayed on-line, data at the time of abnormality determined to be abnormal may be left on the display screen.

  The first suction unit 7 sucks odor gas and the like generated in the preparation tank and sends them to the septic tank 10. The septic tank 10 contains a purifying material, for example, an aqueous hydrogen solution in the case of hydrogen sulfide, and the hydrogen sulfide is purified by a gas-liquid contact method in which the sucked gas is submerged in the aqueous alkali solution.

  A second suction unit 17 is connected to the housing 18, and the interior of the housing 18 is sucked and decompressed when the preparation tank 1 is in operation. As a result, the air pressure inside the housing 18 can be kept lower than the outside air. For this reason, even if the odor gas leaks when the preparation tank 1 is opened and closed, it can be prevented from flowing out of the casing 18. Further, the casing 18 may be provided with a ventilation port for adjusting the internal pressure. By providing the ventilation port, the inside of the housing 18 is prevented from being in an unnecessarily low pressure state.

The control unit 14 determines whether the data measured by the refractometer 2, the tachometer 3, the thermometer 4, and the pressure gauge 5 is within a preset management value range, and the measurement data is out of range. At some time, an operation command is sent to the PLC 8 as an abnormal signal.
And PLC8 which received the abnormal signal outputs an operation signal to the temperature adjustment part 16, the inhibitor injection | throwing-in part 12a, and the alarm device 6. FIG. Thereby, the temperature adjustment unit 16 starts cooling the mixing tank 1 by circulating cooling water around the mixing tank. Further, since the inhibitor charging unit 12a directly inputs the reaction inhibitor into the blending tank 1 based on the control of the PLC 8, it is possible to suppress the progress of the abnormal reaction of the lens material in the blending tank 1. And when it is required according to the raw materials to be blended, cooling water is further poured into the blending tank 1 from the cooling water charging section 12b.

  As described above, in this embodiment, since the operator can perform the abnormality processing without directly touching the apparatus, the operation is greatly simplified and it is possible to avoid unnecessary gas exposure to the operator. In addition, the time loss until the abnormality process is started can be reduced.

Moreover, as a meter which checks the state of the lens material at the time of mixing, as described above, the thermometer 4 for measuring the temperature of the lens material at the time of mixing, and the rotation speed of the stirrer 15 for stirring the lens material at the time of mixing. The tachometer 3 is preferably provided.
As described above, the mixing tank 1 is provided with the thermometer 4 and the tachometer 15 rotation meter 3, and based on the data measured by these, the controller 14 issues a command to the PLC 8 when the mixing is abnormal, and the temperature adjustment and Since the introduction of the inhibitor can be performed automatically, it is possible to reliably monitor the blending abnormality.
The plastic lens manufacturing apparatus 100 according to the present embodiment also includes a refractometer 2 that measures the refractive index of the lens material in the preparation tank 1. For this reason, the progress of the reaction when the lens raw material is prepared can be monitored more reliably.
In particular, since the pressure gauge 5 for measuring the pressure in the blending tank 1 is provided, the blending state can be monitored by gas generated in the lens material blending process, expansion of the lens material, and the like.

Further, a gas detector that detects unnecessary gas such as odor gas may be connected to the second suction part 17. In this case, data measured by the gas detector is sent to the control unit 14, and the control unit 14 determines whether or not the odor gas concentration value is within the management value range. When a value exceeding the control value range is detected by the gas detector, the alarm device 6 is activated by the PLC 8.
By doing in this way, even if unnecessary odor gas etc. leaks, since the alarm device 6 is operated in a state of being kept in the casing 18, it is possible to prevent the operator from being exposed to the odor gas or the like. .

2. Control Procedure of Plastic Lens Manufacturing Device (1) Flowchart of Compounding Process The operation and control procedure of the plastic lens manufacturing device 100 according to the present embodiment will be described with reference to FIG. The following example shows the case where a material for a high refractive index lens is prepared. For example, a lens raw material made of an episulfide compound and an inorganic compound containing a sulfur atom such as sulfur are mixed and reacted to produce a high refractive index plastic lens. The example applied when obtaining a material is shown. However, the present invention is not limited to this, and can be applied to other various plastic lens raw material preparation processes.
First, before starting the blending process, the second suction part 17 is operated to maintain the atmosphere in the housing 18 in a reduced pressure state with respect to the outside air. This state is preferably continued until the end of the preparation process.
The material is charged when the inside of the housing 18 is appropriately decompressed.
In the melting step, the lens raw material and sulfur charged in the preparation tank 1 are heated and dissolved (step S1), and in the reaction step, the lens raw material and sulfur are reacted (step S2).

Next, in the cooling process, the lens material after the reaction is cooled (step S3). When the cooling is finished, the deaeration process is finally performed in the deaeration process (step S4). Here, in the cooling step and the deaeration step, the inside of the preparation tank 1 is depressurized by the first suction unit 7 to remove the generated unnecessary gas, in this case, hydrogen sulfide.
The gas such as hydrogen sulfide sucked here is sent to the septic tank 10 and purified, and then exhausted by the exhaust unit 11. Thus, since the generated unnecessary gas is directly purified as it is, it is possible to suppress a specific odor and to avoid leakage to the outside.
When this deaeration process is completed, the preparation of the lens material is completed, and although not described here, for example, the prepared lens material is filtered and injected into a lens mold to be heated and cured. Then, the mold is released from the lens mold to complete a thermosetting plastic lens.

  In the case of completing as an optical product, a cured film, an antireflection film, and the like are appropriately formed after lens molding. For example, when applied to a lens for spectacles, a primer layer that imparts impact resistance is formed after molding, for example, if necessary, and a cured film, an antireflection film, a water-repellent film, etc. are formed as appropriate to form a spectacle lens. A plastic lens can be provided.

(2) Flowchart of Control Procedure As a typical example, an example of a flowchart from a melting process to a deaeration process will be shown below with reference to FIGS. 6 to 7, and the operation and control of the plastic lens manufacturing apparatus 100 according to the present embodiment Explain the procedure. This example also shows a case where a material for a high refractive index lens is prepared, but the present invention is not limited to this, and can be applied to other various plastic lens raw material preparation steps.
Here, the operation and the control procedure in the reaction process and the deaeration process will be described in particular, but the same logic is formed in the melting process and the cooling process, and the program is appropriately changed depending on the material type and the like.

a. Flowchart of Reaction Process FIG. 6 is a flowchart showing an example of the operation and control method in the reaction process from the melting process to the reaction process of the plastic lens manufacturing apparatus 100 according to the present embodiment.
In the melting process, when the lens raw material and sulfur are charged into the blending tank 1, sulfur is first dissolved in the lens raw material with heating (step S5). Thereafter, the process proceeds to a reaction step, where the catalyst is charged to react the lens material with sulfur (step S6).

Here, if the heating in the preparation tank 1 proceeds and the high temperature state continues and the reaction with sulfur proceeds excessively, the lens raw material may be gelled and not become a resin, and further may be blackened.
If the lens raw material becomes black, it may affect the working environment, such as generating odor or heat, which may be undesirable for the worker.

In this reaction step, it is preferable to monitor the pressure, refractive index, temperature, and rotational speed, and the refractive index and rotational speed data of the lens material in the preparation tank 1 measured by the refractometer 2 and the rotational speed meter 3 are controlled by the control unit. 14.
Similarly, the temperature of the lens material in the preparation tank 1 measured by the thermometer 4 and the pressure gauge 5 and the gas pressure data in the preparation tank 1 are also sent to the control unit 14. Then, the control unit 14 determines whether or not the measured pressure, refractive index, temperature, and rotation speed values are within preset management values (steps S7 to S10).

  These determinations may be performed in series in a predetermined order, but may be performed in parallel as illustrated. For example, when the measured temperature exceeds the management value range, the control unit 14 outputs an abnormality signal to the PLC 8. PLC8 which received the abnormal signal outputs an operation signal to the arbitrary places of the alarm device 6, the temperature adjustment part 16, and the inhibitor injection | throwing-in part 12a and the cooling water injection | throwing-in part 12b. As an example, the alarm device 6 is sounded, and a reaction inhibitor is introduced into the preparation tank 1 from the inhibitor charging unit 12a to suppress the progress of the abnormal reaction. Further, cooling water or the like is sent from the temperature adjusting unit 16 to the periphery of the mixing tank 1 to cool the inside of the mixing tank 1 (step S11). In addition, depending on the lens material, the cooling water charging unit 12b may be performed in the preparation tank 1, but the cooling water charging is omitted when the cooling water charging is not appropriate.

Similarly, when any one of the pressure, the refractive index, and the rotation speed exceeds the control value range, the control unit 14 outputs an abnormal signal to the PLC 8, and the PLC 8 includes the alarm device 6 and the inhibitor charging unit 12a. Arbitrary portions of the temperature adjusting unit 16 and the cooling water charging unit 12b are operated. In particular, when the pressure exceeds the control value, the PLC 8 may operate the first suction unit 7 to depressurize the preparation tank 1.
At this time, information such as a value exceeding the management value range, its data type, and time may be displayed on the display unit 13.

  When the pressure, the refractive index, the temperature, and the rotational speed are all within the control value range (NO in steps S7 to S10), the process waits until the refractive index reaches a predetermined value. At the same time as the predetermined value is reached, it is confirmed whether the melting temperature, pressure, rotation speed, and elapsed time are within the management range (step S12). These values are all within the control value, and when the dissolution or reaction is completed, the process proceeds to the next cooling step (Yes in step S12). If not completed, the PLC 8 recognizes that it is abnormal, and upon receiving the abnormal signal, the PLC 8 activates an alarm, and further performs processing such as cooling of the mixing tank 1, reaction inhibitor, and cooling water depending on the lens material. It is. As a result, the lens material is properly processed.

As described above, in the present embodiment, when even one of the data monitored in each process exceeds the range of the control value, the PLC 8 that has received the abnormal signal activates an alarm, and further cools the preparation tank 1 and the reaction inhibitor. And so on. For this reason, it is possible to more reliably detect a blending abnormality occurring in the blending tank 1. In addition, since the initial response to the blending abnormality can be performed without the operator's operation, it is possible to perform quick processing and reduce the burden on the operator.
In addition, although the monitoring method of the preparation state in the reaction process was described here, it is a matter of course that the same logic can be formed in the dissolution process to monitor the preparation abnormality in the dissolution process.

b. FIG. 7 is a flowchart showing the flow from the cooling step to the deaeration step. In particular, the operation and control method in the deaeration process will be described here.
When the reaction process is finished, cooling water is circulated around the preparation tank 1 from the temperature adjusting unit 16 to cool the preparation tank 1 that has risen in the reaction process (step S13). When this cooling is completed, the additive is added and the process proceeds to a pressure reduction process (step S14).
The plastic lens manufacturing apparatus 100 according to the present embodiment monitors the pressure, refractive index, temperature, and rotation speed of the stirrer 15 in the preparation tank 1 even during the decompression process.
That is, the respective data measured by the refractometer 2, the tachometer 3, the thermometer 4, and the pressure gauge 5 are sent to the control unit 14, and it is determined whether or not they are within a preset management value range. (Steps S15 to S18). If any one of the refractive index, rotation speed, temperature and pressure exceeds the range of the control value, an abnormality is detected (YES in steps S15 to S18), and an abnormality signal is output to the PLC 8.

  And PLC8 which received the abnormal signal outputs an operation signal to the arbitrary places of the alarm device 6, the cooling water injection | throwing-in part 12b, the inhibitor injection | throwing-in part 12a, and the temperature adjustment part 16, and sounds an alarm, for example from the inhibitor injection | throwing-in part 12a A reaction inhibitor is added to the mixing tank 1. And the temperature adjustment part 16 sends cooling water around the mixing tank 1, and cools the mixing tank 1 (step S11). Further, during this process, depending on the lens raw material, the cooling water may be supplied from the cooling water input unit 12 b into the preparation tank 1.

  When the refractive index reaches a predetermined value, it is determined whether or not the deaeration process has been completed normally (step S19). Here, it is determined again whether the rotational speed, temperature and pressure are within the range of the control values. If these are all within the control values and the deaeration process has been completed normally, the process proceeds to the next process (Yes in step S19). If it is outside the control value, the PLC 8 recognizes that it is abnormal, and the PLC 8 that receives the abnormal signal activates an alarm, and further performs processing such as cooling of the preparation tank 1 or reaction inhibitor, or depending on the lens material, cooling water. (NO in step S19). As a result, the lens material is properly processed.

Although not described here, it is preferable to monitor the blending state by measuring the refractive index, the number of revolutions, the temperature, and the pressure with the same logic in the cooling process. In addition, when the gas generated in the dissolving step S1 is mixed while being exhausted by the first suction unit 7, monitoring of the pressure value in the mixing tank 1 may be omitted as appropriate. However, in the deaeration process, it is desirable to measure and monitor the pressure value in order to manage the degree of deaeration.
Further, not only in the steps taken up in the present embodiment, but also when there are other steps such as a polymerization step in which a monomer is added to the lens material after the dissolution step S1 and polymerized, the refraction in that step is similarly performed. The rate, rotation speed, temperature, and pressure may be monitored. The measurement values to be monitored need not be all four types, and only necessary data types may be monitored in accordance with each process. However, it is most preferable to always perform measurement over time, and it is better to manage the management value for each process according to the process time.

As described above, according to the present invention, it is possible to suppress the diffusion of unnecessary gas such as odor gas generated at the time of lens material preparation. For this reason, the operator can work without being exposed to odors, and can reduce the work.
The present invention is not limited to the examples described in the above-described embodiments, and can be applied to various processes during the preparation of the plastic lens material, and can be appropriately modified without departing from the gist of the present invention. It goes without saying that changes are possible.

  DESCRIPTION OF SYMBOLS 1 ... Preparation tank, 2 ... Refractometer, 3 ... Tachometer, 4 ... Thermometer, 5 ... Pressure gauge, 6 ... Alarm, 7 ... 1st Suction part, 8 ... PLC, 9 ... buffer tank, 10 ... septic tank, 11 ... exhaust part, 12a ... inhibitor charging part, 12b ... cooling water charging part, 13 ... -Monitor, 14 ... Control part, 15 ... Stirrer, 16 ... Temperature adjustment part, 17 ... Second suction part, 18 ... Housing, 19 ... Housing, 20 ... Window, 20a ... Door, 21 ... Insertion hole, 22 ... Glove part

Claims (6)

A compounding tank for compounding lens materials;
A first suction part for exhausting the gas in the preparation tank;
An instrument to check the state of the lens material at the time of compounding;
A temperature adjustment unit for adjusting the temperature in the preparation tank;
An inhibitor charging unit for charging a reaction inhibitor into the preparation tank;
A control unit that determines an abnormality in the blending state based on measurement data measured by the instrument;
A programmable logic controller connected to the control unit and performing operation control of the temperature adjusting unit and the inhibitor charging unit based on the determination of the control unit,
A housing that seals and covers at least the periphery of the mixing tank;
A plastic lens manufacturing apparatus comprising: a second suction unit that sucks and exhausts the inside of the housing. A display unit connected to the control unit;
2. The plastic lens according to claim 1, wherein information on measurement data measured by the instrument is constantly displayed on the display unit over time, and highlighting is performed when the control unit determines an abnormality in the blending state. Manufacturing equipment. Furthermore, an alarm is provided,
The said programmable logic controller is a manufacturing apparatus of the plastic lens of Claim 1 or 2 which performs operation | movement control of the said alarm device based on the judgment of the said control part.   The plastic lens manufacturing apparatus according to claim 1, further comprising a septic tank that purifies the gas exhausted by the first suction unit.   The plastic lens manufacturing apparatus according to claim 1, wherein the second suction unit includes a detector for a predetermined gas.   The plastic lens manufacturing apparatus according to any one of claims 1 to 5, wherein the air pressure in the housing is maintained lower than the air pressure outside the housing by the second suction unit at least during operation of the preparation tank.

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