KR101080138B1 - high temperature and low velocity syringe pump system for solid melting injection - Google Patents

Abstract

The present invention relates to a high temperature low speed syringe pump system for solid melt injection for injecting a small amount of solid sample in a quantitative manner.

The high temperature low speed syringe pump system for solid-fusion injection of the present invention has a discharge port provided with a valve 1 for discharging the solid sample melted in the front, a gas discharge port provided with a valve 2 in the upper side is formed, A syringe body having a supply port provided with a valve 3 for receiving a solid sample, and having a heating means to melt the solid sample; A syringe piston moving left and right along the syringe body; A solid sample supply device for supplying a solid sample to a supply port formed in the syringe body; Drive means for moving the syringe piston left and right; Consists of a control unit for controlling the discharge flow rate of the solid sample stored in the syringe body by controlling the movement of the syringe piston.

Solid, high temperature, melting, syringe pump, system

Description

High temperature and low velocity syringe pump system for solid melting injection

The present invention relates to a high temperature low speed syringe pump system for solid melt injection for injecting a small amount of solid sample in a quantitative manner.

In general, solid samples such as naphthalene and urea exist in solid form at room temperature and are melted in a high temperature container to make a liquid state, and then injected into a reactor using a gas as a carrier, or in the case of urea It is made into an aqueous solution and injected.

When using a high temperature vessel (Vessel) as described above to measure the amount supplied to the reactor in accordance with the flow rate of the carrier gas (carrier gas), in this case, the amount of measurement, depending on the amount and characteristics of the carrier gas (carrier gas) Dosing is difficult because of the disadvantage.

When supplied in the form of an aqueous solution, when the viscosity is high, a small amount cannot be injected into a device such as a masterflex.

In addition, when using a carrier gas (carrier gas) as described above, there is a disadvantage that the carrier gas (carrier gas) is supplied together in the reactor, the water is supplied together in the reactor when supplied in the form of an aqueous solution.

The prior art proposed for quantitatively supplying a solid material (sample) is provided with a quantitative supply system of a solid material using a screw feeder of Korean Patent Registration No. 873658.

The quantitative supply system for solid raw materials using the screw feeder of Korean Patent Registration No. 87,3658 is not a device for melting and supplying a solid sample, but a device for supplying a solid state, which is different from the present invention and its configuration, and quantitatively There is a disadvantage that can not supply.

The present invention has been invented to solve the conventional problem of not supplying a solid sample in a small amount in a reactor, and melts by heating the supplied solid sample and melts the gas (air) contained in the container. It is an object of the present invention to provide a high-temperature low-speed syringe pump system for injecting a solid melt which can be supplied in a small amount by discharging the generated gas and supply a small amount while removing a supply of unnecessary gas.

That is, an object of the present invention is to provide a high-temperature low-speed syringe pump system for injecting a solid melt so that a small amount of solid sample can be quantitatively supplied to the reactor for accurate testing.

The high temperature low speed syringe pump system for solid-fusion injection of the present invention to achieve the above object,

A discharge port having a valve 1 for discharging the solid sample melted at the front is formed, a gas discharge port having the valve 2 is formed at the upper side, and a supply port having a valve 3 receiving the solid sample at the rear is formed. A syringe body provided with heating means to melt the solid sample; A syringe piston moving left and right along the syringe body; A solid sample supply device for supplying a solid sample to a supply port formed in the syringe body; Drive means for moving the syringe piston left and right; Consists of a control unit for controlling the discharge flow rate of the solid sample stored in the syringe body by controlling the movement of the syringe piston.

The syringe body may be further formed with a confirmation window for checking the inside,

The solid sample supply device includes a supply pipe having a hopper for storing a solid sample, a moving screw shaft for moving a solid sample stored in the hopper, and a motor for rotating the moving screw shaft.

The drive means includes a drive motor for forward rotation and reverse rotation, a screw shaft which rotates by receiving power from the drive motor, and is installed in parallel with the axis of the syringe body, and is installed on the screw shaft to rotate the screw shaft. It consists of a connecting member for moving the syringe piston to move left and right along the screw shaft according to the direction.

The gas outlet of the syringe body may be further provided with a detection sensor for detecting that the dissolved solid sample is discharged,

The syringe body may be further provided with a pressure sensor and a temperature sensor for measuring the pressure and temperature in the syringe body, a flow sensor for detecting the discharge flow rate may be further installed at the outlet.

The high-temperature low-speed syringe pump system for solid-fusion injection of the present invention thus constructed is a pure molten solid by melting a solid sample and then discharging the gas generated during melting and air in the syringe body to the outside and then supplying it into the reactor. There is a feature that only the sample can be fed into the reactor.

In addition, it is easy to measure the flow rate supplied by supplying the solid sample melted in the syringe body by the syringe piston moving at a low speed, it is characterized in that a small amount of the solid sample can be supplied quantitatively.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 and 2 show a preferred embodiment of the high temperature low speed syringe pump system for solid-fusion injection of the present invention, Figure 1 is a front sectional view, Figure 2 is a plan view.

The high temperature low speed syringe pump system for solid-fusion injection of the present invention is large as shown in FIGS. 1 and 2, the base 10, the syringe body 20 installed on the base 10, and the syringe body ( A syringe piston 30 having one end inserted into the inside of the cylinder 20, a driving means 40 for moving the syringe piston 30 left and right, and a solid sample supplied into the syringe body 20. It is composed of a solid sample supply device 50 and a control unit 60.

The base 10 is usually made of a metal plate so that the high temperature low speed syringe pump system for solid melt injection is structurally stable.

The syringe body 20 is a container for supplying and melting a solid sample, one end of which is blocked, and the other end of the syringe body 20 is formed in a pipe shape in which the syringe piston 30 is opened.

An outlet 21 for dissolving the molten solid sample is formed at the closed portion of the front end, a gas outlet 22 is formed at the upper side, and a solid sample supply port 23 is formed at the rear end, and the inside is checked at one side. A confirmation window 27 is formed. Usually, the gas outlet 22 is formed above the front end of which the outlet 21 is formed, and the syringe body 20 in which the gas outlet 22 is formed above the front end is sheared to facilitate the discharge of air therein. It is preferable to be inclined so that an addition may be higher than a rear end part.

In addition, a pressure sensor 24 and a temperature sensor 25 capable of measuring the internal pressure and temperature of the syringe body 20 are installed, so that the solid sample supplied to the syringe body 20 can be melted. Heating means 26 is provided. The heating means 26 usually uses a heating wire that generates heat by a power source (current) supplied to the outside.

A valve 1 (V1) and a flow sensor 21a are installed at the outlet 21, a valve 2 (V2) and a sensor 22a are installed at the gas outlet 22, and a valve 3 is provided at the supply port 23. V3 is installed.

The valves 1,2,3 (V1, V2, V3), the flow sensor 21a, the sensor 22a, the pressure sensor 24, the temperature sensor 25 and the heating means 26 are connected to the control unit 60. Electrically connected to provide information and control.

That is, the controller 60 measures the internal pressure and temperature of the syringe body 20 by the pressure sensor 24 and the temperature sensor 25, and controls the heating means 26 to control the syringe body 20. ) Is heated to melt the solid sample supplied therein, and the valves 1,2,3 (V1, V2, V3) are controlled to control the supply of the solid sample and the discharge of the gas and the melted solid sample.

The syringe piston 30 discharges the melted solid sample in the syringe body 20 to the discharge port 21, and is inserted into the opening of the syringe body 20 and moved left and right in the drawing.

The drive means 40 moves the syringe piston 30 from side to side, the drive motor 41, the screw shaft 42 rotated by the drive motor 41, and the screw shaft 42 It consists of a connecting member (43) to move left and right in accordance with the rotation direction of the, and a reducer (44) to rotate the screw shaft (42) by slowing down the number of rotation of the drive motor (41).

 The drive motor 41 usually uses a motor for forward rotation and reverse rotation, and a low speed motor may be used so as not to use the reduction gear 44.

Both ends of the screw shaft 42 are supported by the bearing, and are installed to be parallel to the central axis of the syringe body 20.

The connecting member 43 moves left and right along the screw shaft 42 in the rotational direction of the screw shaft 42 and is connected to the syringe piston 30.

The speed reducer 44 is installed between the drive motor 41 and the screw shaft 42 to reduce the rotation speed of the drive motor 41 to transfer power to the screw shaft 42.

The drive motor 41 of the drive means 40 is electrically connected to the control unit 60 and controlled by the control unit 60.

That is, the controller 60 controls the movement of the cylinder piston 30 connected to the connecting member 43 by controlling the driving distance and the rotational direction of the driving motor 41 to adjust the moving distance of the connecting member 43. .

The solid sample supply device 50 is a supply pipe 53 having a hopper 51 for storing a solid sample, a moving screw shaft 52 for moving the solid sample stored in the hopper 51, and the moving screw It is composed of a motor 54 for rotating the shaft 52 to supply a solid sample inside the syringe body (20).

The motor 54 of the solid sample supply device 50 is electrically connected to the control unit 60 and controlled by the control unit 60.

That is, the controller 60 controls the driving of the motor 54 to control the solid sample introduced into the thinner body 20 through the supply port 23.

The control unit 60 receives information from various sensors installed in the cylinder body 20 and controls various valves, driving means 40 and solid sample supply device 50 to appropriately dissolve the melted solid sample into the reactor. To supply.

The control unit 60, the flow rate discharged to the discharge port 21 in accordance with the information about the movement distance of the syringe piston 30 by the normal drive means 40, and the movement distance of the syringe piston 30. Information about is entered.

3 shows the movement distance S of the syringe piston 30 according to the rotational speed RPM of the screw shaft 42 of the drive means 40, and the rotational speed RPM of the screw shaft 42 and The moving distance S of the syringe piston 30 has a proportional relationship.

As shown in Figure 4 shows the flow rate (Q) of the melted solid sample discharged to the outlet 21 of the syringe body 20 according to the movement distance (S) of the syringe piston 30, the syringe piston 30 ) Has a proportional relationship with the moving distance S and the flow rate Q.

The high temperature low speed syringe pump system for solid fusion injection of the present invention made as described above operates as follows.

(Iii) The control unit 60 rotates the motor 54 of the solid sample supply device 50 to supply the solid sample stored in the hopper 51 to the syringe body 20, and when the supply is completed, the motor (54) is stopped and valve 3 (V3) is shut off.

(Ii) The control unit 60 melts the solid sample supplied to the syringe body 20 by the heating means 26. The gas generated at this time (when melting the solid sample) is discharged to the gas outlet 22 (valve 1 (V1) and valve 3 (V3) are closed, valve 2 (V2) is open).

 (Iii) The control unit 60 operates the drive means 40 to discharge the gas existing in the syringe body 20 and the gas generated during melting of the solid sample to the gas outlet 22 (gas outlet 22). If a solid sample is detected by the sensor 22a installed in the valve, the valve 2 (V2) is blocked).

(Iii) The control unit 60 opens the valve 1 (V1) so as to discharge the amount of solid sample to be supplied into the reactor, and moves the syringe piston 30 to the driving means 40 to be melted toward the outlet 21. The solid sample is discharged and fed to the reactor.

The flow rate supplied to the reactor is measured by measuring the discharge flow rate according to the moving distance of the syringe piston 30, or measured by the flow rate sensor (21a) installed in the discharge port (21).

1 is a front schematic view of a high temperature low speed syringe pump system for solid melt injection showing a preferred embodiment of the present invention.

Figure 2 is a top schematic view of a high temperature low speed syringe pump system for solid melt injection showing a preferred embodiment of the present invention.

3 is a graph showing the movement distance (S) of the syringe piston according to the rotational speed (RPM) of the screw shaft.

Figure 4 is a graph showing the flow rate (Q) of the melted solid sample discharged to the outlet according to the movement distance (S) of the syringe piston.

DESCRIPTION OF THE REFERENCE NUMERALS

10: Base

20: syringe body 21: outlet

22: gas outlet 23: supply port

21a, 22a, 24, 25: sensor 26: heating means

27: confirmation window

30: syringe piston

40: drive means 41: drive motor

42: screw shaft 43: connecting member

44: reducer

50: solid sample supply device 51: hopper

52: moving screw shaft 53: supply pipe

54: motor

60: control unit

Claims (11)

A discharge port 21 having a valve 1 for discharging the solid sample dissolved in the front is formed, and a gas discharge port 22 having a valve 2 is formed at the upper side, and a valve 3 receiving the solid sample at the rear is provided. A syringe port 20 having a supply port 23 formed therein and having a heating means 26 to melt the solid sample; A solid sample supply device (50) for supplying a solid sample into the syringe body (20) through the supply port (23) formed in the syringe body (20) ; A syringe piston 30 which moves left and right along the syringe body 20; Drive means (40) for moving the syringe piston (30) left and right; It includes a control unit 60 for adjusting the discharge flow rate of the solid sample stored in the syringe body 20 by controlling the movement of the syringe piston 30, The control unit 60 moves the syringe piston 30 to the driving means 40 so that the solid sample is melted by the gas and the heating means 26 present in the syringe body 20. After discharging the generated gas through the gas outlet 22, the solid sample melted by the heating means 26 is controlled through the outlet 21 by controlling the movement of the syringe piston 30. A high temperature low speed syringe pump system for injecting solids, characterized in that the discharge . The method of claim 1, The syringe body (20) is a high-temperature low-speed syringe pump system for solid melt injection, characterized in that the confirmation window 27 is further formed to check the interior. The method of claim 1, The solid sample supply device 50, the supply pipe 53 having a hopper 51 for storing a solid sample, a moving screw shaft 52 for moving the solid sample stored in the hopper 51, and High temperature low speed syringe pump system for solid melt injection, characterized in that consisting of a motor (54) for rotating the moving screw shaft (52). The method of claim 1, The drive means 40, a drive motor 41 for forward rotation and reverse rotation, Rotating power received from the drive motor 41, the screw shaft 42 is installed in parallel with the axis of the syringe body 20, the screw shaft 42 is installed in the rotation of the screw shaft 42 High temperature low speed syringe pump system for solid melt injection, characterized in that consisting of a connecting member 43 for moving the syringe piston 30 to move left and right along the direction of the screw shaft (42). The method of claim 4, wherein High-temperature low-speed syringe pump system for solid melt injection, characterized in that the reducer 44 is installed between the drive motor (41) and the screw shaft (42) to the low speed rotation. The method of claim 1, When gas is discharged through the gas outlet 22, the valve 1 and the valve 3 are closed, and the valve 2 is open, When the molten solid sample is discharged through the outlet 21, the valve 1 is open, the valve 2 is closed high temperature low speed syringe pump system, characterized in that the closed state. The method according to claim 1 or 6, The gas outlet 22 of the syringe body 20 is formed on the front end side in which the outlet 21 is formed, and the syringe body 20 is inclinedly installed so that the front end is high. Low speed syringe pump system. The method of claim 1, The gas outlet 22 of the syringe body 20 is further provided with a detection sensor for detecting that the dissolved solid sample is discharged, The high temperature low speed syringe pump system for solid melt injection, characterized in that the valve 2 is closed when it is detected that the solid sample melted in the gas outlet 22 is discharged by the sensor. The method of claim 1, The syringe body 20 is a high-temperature low-speed syringe pump system for solid melt injection, characterized in that the pressure sensor 24 and the temperature sensor 25 for measuring the pressure and temperature in the syringe body 20 is installed. The method of claim 1, The outlet 21 of the syringe body 20 is a high-temperature low-speed syringe pump system for solid melt injection, characterized in that it further comprises a flow sensor. The method of claim 1, The control unit 60, the flow rate discharged to the outlet 21 according to the information on the moving distance of the syringe piston 30 by the drive means 40, and the moving distance of the syringe piston 30 The high temperature low speed syringe pump system for solid melt injection, characterized in that information is input.

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