KR101851847B1 - Temperature measurement device for nozzle using cooling water flow and temperature - Google Patents

Abstract

More particularly, the present invention relates to a nozzle temperature measuring apparatus for measuring the temperature of a nozzle used in a cold runner using liquid silicon and measuring the temperature of the nozzle according to the condition of the nozzle or the flow rate or temperature of the cooling water. The present invention relates to a nozzle temperature measuring apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water, which can maximize the service life of the nozzle by checking the temperature in accordance with the curing conditions of the liquid silicone.
According to an aspect of the present invention, there is provided a measuring instrument comprising: a measuring instrument main body having a nozzle inserting portion to which a nozzle to be measured is inserted; A cooling water measuring unit communicating with one side of the main body of the measuring device and including a water inlet pipe having a first temperature sensor and a first flow meter and a water outlet pipe communicating with the other side of the main body of the measuring device; And a third temperature sensor for measuring an end temperature of the nozzle.

Description

TECHNICAL FIELD [0001] The present invention relates to a device for measuring a nozzle temperature according to a difference between a flow rate of a cooling water and a temperature of the nozzle.

More particularly, the present invention relates to a nozzle temperature measuring apparatus for measuring the temperature of a nozzle used in a cold runner using liquid silicon and measuring the temperature of the nozzle according to the condition of the nozzle or the flow rate or temperature of the cooling water. The present invention relates to a nozzle temperature measuring apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water, which can maximize the service life of the nozzle by checking the temperature in accordance with the curing conditions of the liquid silicone.

Liquid Silicone Rubber (LSR) is generally referred to as silicone which is solidified when heated in a liquid rubber, while liquid silicone rubber (LSR; The liquid silicone rubber has the basic properties of silicone rubber and is liquid, which makes it easy to modify, mix and form. Therefore, it is used for manufacturing various industrial products such as baby products and household goods, as well as automobile parts and electric and electronic parts, and the use range thereof is gradually increasing.

A cold runner is a molding method using liquid silicone rubber which cools liquid silicone rubber, which hardens when heated, to cool the silicone so that it does not harden before it is injected into the mold through the nozzle.

1 is a view showing an example of a cold runner and a nozzle structure used in the cold runner.

Referring to FIG. 1, a nozzle 10 used in a condenser includes a sprue hole 30 through which liquid silicone rubber passes and a cooling channel 50 provided outside the sprue hole 30. The sprue hole 30 is formed through the center portion along the longitudinal direction of the nozzle 10 and the cooling channel 50 is configured to surround the sprue hole 30. [ The inlet 53 of the cooling channel 50 is provided on one side adjacent to one end of the nozzle 10 and the outlet 55 is provided on the opposite side (the other side) of the inlet. The cooling channel 50 provided on the outside of the sprue hole 30 is configured to surround the sprue hole 30 in a semi-cylindrical shape, and both sides thereof are communicated with each other.

In the above configuration, the cooling water enters through the inlet 53 provided at one side of the nozzle 10, flows to the other side through the other end direction, and then is discharged through the outlet 55 in the one end direction. Thereby preventing the liquid silicone rubber passing through the sprue hole 30 from being hardened in the nozzle before being heated by the heating plate 70 and injected into the mold.

The reason why the nozzle 10 is cooled through the cooling channel 50 is that when the liquid silicone rubber passing through the sprue hole 30 of the nozzle 10 is heated before passing through the sprue hole 30 And the silicon injection is obstructed by clogging in the inside of the sprue hole 30. A device for applying heat to the mold 90 such as a heating plate 70 or the like is provided in front of the outer surface of the nozzle 10 in order to harden the liquid silicone rubber completely injected into the mold 90 into the shape of the mold 90 Respectively. Thus, the silicon is cooled by the heating plate 70 through the cooling channel 50 so that the silicone does not harden until the silicon completely passes through the nozzle 10. [

Since the cooling channel 50 is not formed at the end of the nozzle 10 used in the cold runner, the influence of the cooling water on the shape and the length of the end portion of the nozzle 10, The structure and shape of the cooling channel 50 may differ depending on the type. Therefore, even if the cooling water having the same temperature and flow rate is used, the temperature at the end of the nozzle 10 may be different. On the other hand, the composition ratio of the liquid silicon used for the cold runner may be varied. In this case, the temperature at which the liquid silicone is cured may be varied.

On the other hand, it is impossible to measure the temperature of the end of the nozzle in the course of actual production by mounting the nozzle 10 on the cold runner. Therefore, for safe production, in order to keep the temperature of the nozzle 10 sufficiently lower than the actual required temperature in order to prevent the cured liquidconcrete rubber from hardening, the cooling water temperature is lowered and the flow rate is increased to cause unnecessary energy consumption. This is because when the flow rate or the temperature of the cooling water passing through the cooling channel 50 of the nozzle 10 is erroneously adjusted to cause the liquid silicone rubber to harden inside the nozzle 10 and the nozzle 10 is clogged, . Therefore, in the case where the kind or shape of the nozzle is changed or the composition or mixing ratio of the liquid running cone rubber to be used is changed, a measurement technique capable of calculating the temperature of the nozzle end portion according to the curing temperature of the liquid silicone rubber, The life of the nozzle can be maximized while minimizing energy consumption by using the measured data.

KR 10-1392281 B1 KR 10-1170547 B1 KR 10-1000357 B1 KR 10-1195932 B1

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a cold runner in which the end portion of the nozzle exhibits a certain temperature value according to the flow rate of coolant and the temperature change, And it is an object of the present invention to provide an apparatus for measuring a nozzle temperature according to a difference between a flow rate and a temperature of a cooling water which can calculate a cooling temperature and a flow rate so that the silicone rubber does not harden in the nozzle while being mounted on a runner.

According to an aspect of the present invention, there is provided a measuring instrument comprising: a measuring instrument main body having a nozzle inserting portion to which a nozzle to be measured is inserted; A cooling water measuring unit communicating with one side of the main body of the measuring device and including a water inlet pipe having a first temperature sensor and a first flow meter and a water outlet pipe communicating with the other side of the main body of the measuring device; And a third temperature sensor for measuring an end temperature of the nozzle.

In a preferred embodiment of the present invention, the measuring instrument main body includes a base portion, a heat insulating portion provided on the other side of the base portion, a heating portion provided on the other side of the heat insulating portion, and a body portion provided on the other side of the heating portion, Wherein the nozzle inserting portion is formed to penetrate the measuring instrument main body from one side to the other side and the third temperature sensor is configured to measure the temperature of the end of the nozzle mounted on the nozzle inserting portion through the other end of the nozzle inserting portion, Wherein the other end of the water inlet pipe communicates with the one side of the nozzle inserting part through the base part and one side of the water outlet pipe communicates with the other side of the nozzle inserting part through the base part.

In a preferred embodiment of the present invention, the other side of the main body is further provided with an expansion portion at a position corresponding to the end of the nozzle so as to prevent the temperature of the main body from being transmitted to the third temperature sensor inserted into the end of the nozzle .

In a preferred embodiment of the present invention, the water outlet pipe is provided with a second temperature sensor and a second flow meter.

In a preferred embodiment of the present invention, the water outlet pipe or the water inlet pipe is further provided with a flow rate control unit.

In a preferred embodiment of the present invention, the measuring instrument body further includes at least two nozzle insertion ports, and one side of the nozzle insertion ports is connected to the other side through a connection pipe.

According to the apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water according to the present invention, the temperature change of the nozzle end can be calculated according to the shape and structure of the nozzle, the flow rate of the cooling water passing through the nozzle, The advantage of being able to control the optimum environment for preventing the liquid silicone rubber from being hardened in the nozzle before the liquid silicone rubber is injected into the mold in consideration of the kind of the liquid silicone rubber and the shape and structure of the nozzle, .

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an example of a cold runner and a nozzle structure used in the cold runner; Fig.
2 is a view showing an example of a nozzle temperature measuring apparatus according to the difference between the flow rate and the temperature of the cooling water according to the present invention.
FIG. 3 is a view showing an expanded portion of the nozzle temperature measuring apparatus according to the flow rate and temperature of the cooling water according to the present invention and a state where the third temperature sensor is provided in the expanded portion.
4 is a view showing a use state of the nozzle temperature measuring apparatus according to the difference between the flow rate and the temperature of the cooling water according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing an example of an apparatus for measuring a nozzle temperature according to a difference between a flow rate and a temperature of cooling water according to the present invention.

Referring to FIG. 2, the apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water according to the present invention may include a main body 100 of the measuring apparatus, a cooling water measuring unit 200, and a third temperature sensor 300 have.

The measuring instrument body 100 may include a base portion 110, a heat insulating portion 130, a heating portion 150, and a body portion 170. The measuring instrument body 100 is preferably configured in the same manner as the environment of the cold runner in which the nozzle 10 is used so as to be able to measure the temperature change in the actual environment in which the nozzle 10 is used. Hereinafter, the configuration of the measuring instrument main body 100 corresponding to the general configuration of the cold runner will be described as an example.

On both sides of the base portion 110, a water inlet pipe 210 and a water drain pipe 260 are extended and a heat insulating portion 130 is provided on the other side as described later. The heating unit 150 is provided with various known heating devices 155 to heat the heating unit 150. The base 110 is cooled by the cooling water flowing through the water inlet pipe 210 and the drain pipe 260 and the heat of the heating unit 150 is blocked by the heat insulating unit 130, .

A heat insulating part 130 is provided on the other side of the base part 110 and a heating part 150 is provided on the other side of the heat insulating part 130. The heat insulating part 130 prevents the heat generated in the heating part 150 from being transmitted to the base part 110 to prevent the nozzle 10 at a portion contacting the base part 110 from being heated, The heat generated in the heating unit 150 is transferred only in the direction of the body unit 170 to heat the body unit 170. Such a configuration is similar to the environment in which the nozzle 10 of the cold runner is used.

The nozzle inserting portion 190 is provided to penetrate from one side of the measuring instrument body 100 described above to the other side. At least two nozzle inserting portions 190 may be provided as needed. 1, the nozzle 10 used in the cold runner is provided with a cooling channel 50 on the outside of the sprue hole 30, and the cooling channel 50 is disposed on both sides of one end of the nozzle 10 An inlet 53 and an outlet 55 are formed respectively. The nozzle 10 is inserted into the nozzle insertion portion 190 and the inlet and the outlet of the nozzle 10 are connected to the inlet pipe 210 extending to the inside of the base 110, And the water outlet pipe 260 so that the cooling water flowing through the water inlet pipe 210 passes through the cooling channel 50 of the nozzle 10 and flows to the water outlet pipe 260. In this case, when two or more nozzle inserting portions 190 are provided in the nozzle temperature measuring apparatus according to the flow rate and temperature of the cooling water according to the present invention, one side and the other side of the inserting holes of the respective nozzles 10 are connected to the connecting pipe 115 Lt; / RTI > According to the above configuration, it is possible to simultaneously measure the case where two nozzles 10 are provided in the cold runner and the case where one nozzle 10 is provided, by using one measuring apparatus. That is, in the case of measuring the environment in which only one nozzle 10 is used in the above configuration, the nozzle 10 is mounted on one nozzle inserting part 190, It is only necessary to insert a jig having a shape corresponding to the nozzle 10 connecting the water supply pipe 115 with the water supply pipe 210 or the water discharge pipe 260.

The cooling water measuring unit 200 includes a water inlet pipe 210 communicating with one side of the measuring instrument body 100 and a water outlet pipe 260 communicating with the other side of the measuring instrument body 100. The water inlet pipe 210 may include a first temperature sensor 230 and a first flow meter 250. The water outlet pipe 260 may include a second temperature sensor 270 and a second flow meter 290. [ have. At this time, the temperature sensor and the flow meter may be provided in both the water inlet pipe 210 and the water outlet pipe 260, and may be provided only in the water inlet pipe 210 if necessary. However, in a preferred embodiment of the present invention, the temperature sensor and the flow meter are provided in both the water inlet pipe 210 and the water outlet pipe 260. This is because the apparatus for measuring the nozzle temperature according to the flow rate and the temperature of the cooling water according to the present invention is not simply a production apparatus in which the temperature of the nozzle 10 is maintained at a temperature at which the liquid silicon is not cured, It is necessary to acquire experimental data such as how much the temperature of the cooling water and the flow rate of the cooling water are warmed at the outlet when the temperature of the nozzle 10 is properly maintained. Meanwhile, in another embodiment of the present invention, the flow control unit 240 may be further provided in the water pipe 260 and the water pipe 210. Thus, the flow rate of the water inlet pipe 210 or the water outlet pipe 260 may be adjusted according to experimental conditions.

The third temperature sensor 300 measures the temperature of the end of the nozzle 10 mounted on the nozzle inserting unit 190 through the other end of the nozzle inserting unit 190. The nozzle 10 used in the cold runner has a cooling channel formed around the sprue hole but the cooling channel can not be provided at the inclined end of the nozzle 10. [ The end of the nozzle 10 can not be directly cooled by the cooling water passing through the cooling channel and indirectly cooled by the heat transfer through the nozzle 10. [ Therefore, even if the temperature of the cooling water supplied through the cooling channel is lowered or the flow rate is increased, the end of the nozzle 10 is heated to a temperature higher than the reference temperature (the temperature at which the silicon is hardened) Accordingly, the third temperature sensor 300 measures the temperature change of the end of the nozzle 10 according to the flow rate or the temperature flowing through the cooling channel of the nozzle 10, while measuring the flow rate of the cooling water required to maintain the temperature of the nozzle end at the reference temperature The temperature, and the time required to constantly lower the end of the nozzle.

FIG. 3 is a view showing an expanded portion of the apparatus for measuring the nozzle temperature according to the flow rate and temperature of the cooling water according to the present invention, and a state where the third temperature sensor is provided in the expanded portion.

1 and 3, an apparatus for measuring a nozzle temperature according to a flow rate and a temperature of a cooling water according to the present invention includes a body portion 170 at an end of the nozzle 10, And further an expansion portion 175 may be formed at a corresponding position. This is because the temperature of the main body 170 is directly transmitted to the third temperature sensor 300 to prevent an error from occurring when measuring the temperature of the end of the nozzle 10. [ The body portion 170 is provided on the other side of the heating portion 150 to directly receive the heat of the heating portion 150 as described above. Therefore, the temperature of the main body 170 becomes equal to or higher than the reference temperature at which the liquid silicon is cured. When the third temperature sensor 300 is inserted into the end portion of the nozzle 10, the heat of the main body portion 170 is transmitted to the third temperature sensor 300 so that the temperature of the end portion of the nozzle 10 is less than the actual temperature Will be high. Accordingly, the expansion portion 175 is provided to secure a predetermined space by removing the body portion 170 located around the third temperature sensor 300. [ The expansion portion 175 is formed to have an area sufficiently separated from the end of the nozzle 10 and the third temperature sensor 300 so that the temperature of the main body portion 170 is not transmitted to the third temperature sensor 300, And can be configured in various sizes and shapes within a range satisfying the conditions.

4 is a view showing a state of use of the apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water according to the present invention.

Referring to FIG. 4, a method of using the apparatus for measuring the nozzle temperature according to the difference between the flow rate and the temperature of the cooling water according to the present invention will be described. The nozzle 10 used in the cold runner is connected to the nozzle inserting unit 190, The temperature of the end of the nozzle 10 can be measured while adjusting the temperature and the flow rate of the water inlet pipe 210 and the water outlet pipe 260. The liquid silicone used in the cold runner may have different curing temperatures depending on the type and mixing ratio thereof, and the curing temperature can be measured in advance through experiments. That is, the temperature at which curing starts to occur while heating the liquid silicon can be experimentally measured. Then, the nozzle 10 to be used for injecting the liquid silicon is attached to the nozzle inserting portion 190 of the nozzle temperature measuring device according to the flow rate and temperature of the cooling water according to the present invention, and the heating portion 150 is driven The temperature of the end of the nozzle 10 is measured using the third temperature sensor 300 while the cooling water is supplied through the inlet pipe 210. Thus, after obtaining the flow rate and temperature data of the cooling water for keeping the temperature measured by the third temperature sensor 300 from reaching the temperature at which the liquid silicone is hardened, the flow rate and the temperature of the cooling water are adjusted in the actual cold runner, 10 can be controlled so as not to reach the curing temperature of the liquid silicon. In addition, the apparatus for measuring the nozzle temperature according to the flow rate and temperature of the cooling water according to the present invention can test various newly developed nozzles before using them, and can use them in an optimal environment without trial and error.

Although the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be determined by the appended claims, as well as the appended claims.

100: Measuring instrument body
110: Base portion
130:
150:
170:
175:
200: Cooling water measuring unit
210: inlet pipe
230: first temperature sensor
240:
250: First flow meter
260: Water pipe
270: second temperature sensor
290: Second flow meter

Claims (6)

A measuring instrument main body having a nozzle inserting portion to which a nozzle to be measured is inserted while being inserted;
A cooling water measuring unit communicating with one side of the main body of the measuring device and including a water inlet pipe having a first temperature sensor and a first flow meter and a water outlet pipe communicating with the other side of the main body of the measuring device;
And a third temperature sensor for measuring an end temperature of the nozzle,
Wherein the main body of the measuring instrument includes a base portion, a heat insulating portion provided on the other side of the base portion, a heating portion provided on the other side of the heat insulating portion, and a main body portion provided on the other side of the heating portion,
Wherein the nozzle inserting portion is formed to penetrate the measuring instrument body from one side to the other side and the third temperature sensor is configured to measure a temperature of an end of a nozzle mounted on the nozzle inserting portion through the other end of the nozzle inserting portion,
The cooling water measuring unit is configured such that the other side of the water inlet pipe communicates with one side of the nozzle inserting unit through the base unit and one side of the water outlet pipe communicates with the other side of the nozzle inserting unit through the base unit A device for measuring nozzle temperature according to flow rate and temperature of cooling water.
delete The method according to claim 1,
Wherein the second temperature sensor is disposed at a position corresponding to an end of the nozzle so that a temperature of the main body is not transmitted to a third temperature sensor inserted into an end of the nozzle. A nozzle temperature measuring device according to claim 1;
4. The method according to any one of claims 1 to 3,
Wherein the water outlet pipe is provided with a second temperature sensor and a second flow meter.
The method of claim 4,
Wherein the water outlet pipe or the water inlet pipe is further provided with a flow rate control unit.
The method of claim 4,
Wherein at least two nozzle insertion ports are further provided in the main body of the measuring instrument, and one side and the other side of the nozzle insertion ports are connected to each other through a connection pipe.

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