KR100805938B1 - Internal pressure measuring equipment - Google Patents

Abstract

The present invention relates to a pressure-resistant measuring device mainly used to measure the change in the internal pressure of a plastic container, the injection gas into the inside of the measurement object (P) with a simple operation of the gas supply control mechanism 80 and the gas discharge mechanism (90). Since it can be injected at an appropriate pressure, the experiment work becomes very convenient, and by adjusting the gas supply control mechanism 80 and the gas discharge mechanism 90 properly, the injection gas is detected at a high concentration inside the measurement object P at a high concentration. It is effective to carry out the pressure-resistance test for better and faster.

Description

Internal pressure measuring equipment

1 is a view schematically showing a pressure resistance measuring apparatus according to the present invention;

Perspective view showing the Y example,

3 is an exploded perspective view of main parts of the workpiece-tightening mechanism shown in FIG. 2;

4 is a partial cross-sectional view showing the main part of the pressure resistance measuring apparatus shown in FIG.

-Explanation of terms for the main parts of the accompanying drawings-

10; Chamber, 20; Pressure sensor,

30; Temperature sensor, 40; Main control unit,

50; Input unit, 51; keyboard,

52; Mouse, 60; Output unit,

61; Display, 62; printer,

70; Injection gas source, 80; Gas supply control mechanism,

90; Gas emission control mechanism, 100; Workpiece confidentiality mechanism,

110; Main body 110a; First Body,

110P; Second body, 111; Guide Hole,

112; First fastening, 113; Second Fastener,

114; Reinforcing ring fixing, 120; Pressing member,

121a; Gas inlet line, 121b; Gas outlet line,

122; First fastening, 123; Sealing ring seating groove,

124; Second fastening portion, 130,130 '; Hanging Member,

131; Hanging jaw, 132; Fastener,

140; Engaging member connecting pin, 150; Auxiliary gas line,

P; Workpiece, P1; projection part,

HS; Humidity sensors, S1, S2, S3; Sealing ring.

The present invention relates to a pressure resistance measuring apparatus, and more particularly, to a pressure resistance measuring apparatus mainly used for measuring the pressure resistance change of a plastic container.

As is well known, various types of pressure-resistant measuring devices for measuring the internal pressure change of a measurement object have been developed and used. The internal pressure measurement of a plastic container for storing carbonic acid solution, such as Korean Patent Registration No. 0540186 The method of measuring internal pressure change using a measuring device is mainly used.

According to this method, the quantitatively measured dry ice is introduced into the plastic container body, the plastic container lid having a pressure sensor for measuring the internal pressure of the plastic container is sealed, and then the sealed plastic container is fixed in a sealed chamber. While storing for a time, the pressure sensor provided on the lid of the plastic container measures the internal pressure change of the plastic container over time, and measures the ambient temperature at the time of measuring the internal pressure of the plastic container using the temperature sensor.

In this case, the pressure resistance test is very simplified, and the pressure resistance test is automatically performed, so that the pressure resistance test is very convenient and accurate.

However, in the case of the prior art, the experimenter must handle dry ice and quantitatively measure it, and after putting the quantitative dry ice into the inside of the plastic container body as a measurement object, the plastic having a pressure sensor as a measurement airtight mechanism Sealing with the container lid allows dry ice to vaporize with CO2 gas inside the sealed plastic container, making preliminary work for pressure resistance measurement very cumbersome and inconvenient.

In addition, the time required for quantitatively measuring dry ice to be sealed in the plastic container body may vary depending on the skill of the operator and the working environment. Since it cannot be the same every time until it is sealed inside the main body of the plastic container, there is a limit to more accurate pressure resistance measurement.

In addition, since the dry ice injected into the plastic container in the sealed state of the plastic container is vaporized with CO2 gas, the CO2 gas concentration of the plastic container is inevitably limited, and the pressure resistance test for the characteristics of the plastic container has not been effectively performed.

Accordingly, the present invention has been invented to solve the problems described above, and an object thereof is to provide a pressure resistance measuring device that allows the pressure resistance measurement experiment of the measurement object to be more convenient and accurate.

The present invention for achieving the above object, the chamber and forming a closed space; A measuring object airtight mechanism which is disposed inside the chamber to seal the measuring object; A pressure sensor installed in the airtight holding mechanism for measuring the internal pressure of the workpiece; A temperature sensor for measuring the internal temperature of the chamber; A main control unit which receives the output signals from the pressure sensor and the temperature sensor, processes the internal pressure change of the workpiece, and stores the data; An input unit for controlling the operation of the main control unit; An internal pressure measuring device having an output unit which is controlled by a main control unit and outputs an experimental result to the outside, the apparatus comprising: a gas inflow line for guiding an injected gas supplied from the outside into the measurement object airtight mechanism; An injection gas supply source for supplying the injection gas to the gas inflow line of the measurement hermetic holding mechanism, while a gas outflow line for guiding the auxiliary gas in the measurement object to the outside is formed; A gas supply control mechanism for controlling an injection gas supply from an injection gas supply source to a gas inlet line; The gas discharge control mechanism for controlling the discharge of the gas inside the workpiece from the gas outlet line of the measurement object airtight mechanism to the outside is reinforced.

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

1, the pressure resistance measuring apparatus according to the present invention includes a chamber 10 for forming a closed space; The gas inlet line 121a which is disposed inside the chamber 10 to seal the measurement object P and guides the injection gas supplied from the outside into the measurement object P, and guides the internal gas of the measurement object to the outside. A measurement hermetic holding mechanism 100 having a gas outlet line 121b; A pressure sensor 20 installed in the measurement object airtight holding mechanism 100 to measure the internal pressure of the measurement object P; A temperature sensor 30 for measuring the internal temperature of the chamber 10; A main control unit 40 which receives the output signals from the pressure sensor 20 and the temperature sensor 30 and processes the internal pressure change of the measurement data and stores the data; An input unit 50 for controlling the operation of the main control unit 40; An output unit 60 which is operated and controlled by the main control unit 40 and outputs an experimental result to the outside; An injection gas supply source 70 supplying the injection gas to the gas inflow line 121a of the measurement object hermetic holding device 100; A gas supply control mechanism 80 for controlling the injection gas supply from the injection gas supply source 70 to the gas inlet line 121a; It consists of a gas discharge control mechanism 90 for controlling the discharge of the gas inside the measurement object from the gas outlet line 121b of the measurement object airtight mechanism 100 to the outside.

The chamber 10 is for controlling the surrounding environment of the measurement object P, and inserts the measurement object P into the chamber 10 to be fastened with the measurement object airtight mechanism 100 or the chamber 10. It has an opening / closing structure which can separate the inside measured object P from the measured object airtight mechanism 100, and can be taken out to the chamber 10 outside.

In the case of this embodiment, the pressure sensor 20 and the temperature sensor 30 is a known one. The main control unit 40 applied a well-known PC desktop, the input unit 50 used a known input means such as a keyboard 51 or a mouse 52, the output unit 60 also Known output means such as a display 61 such as a monitor or a printer 62 were used. CO2 gas was applied as the injection gas supplied from the injection gas supply source 70. As the gas supply control mechanism 80, a known manual ball valve is applied, and as the gas discharge control mechanism 90, a known push valve is applied.

The measuring object hermetic holding mechanism 100 can be applied to anything that can be detachably fastened to the measuring object (P) to seal the measuring object (P), depending on the type and shape of the measuring object (P) Therefore, although various modifications can be made, in this embodiment, the plastic container is applied as the measurement object P, and the measurement object hermetic holding device 100 as shown in FIGS. 2 to 4 is measured object P. ) To maintain the airtightness of the measured object (P).

Referring to Figures 2 to 4, the measurement object airtight mechanism 100 will be described as follows.

2 to 4, the measurement object airtight mechanism 100, the main body 110 which is fixed to the neck of the bottle, a pair of locking members (130, 130 '), the neck of the measurement object (P) Equipped with a sealing ring (S1) to seal the upper and lower reciprocating movement to the main body 110 is made of a pressing member 120 is threaded.

The main body 110 is provided with a guide hole 111 penetrating the inside in the vertical direction, the first fastening portion 112 having a thread formed on the inner circumferential surface of the guide hole 111 is provided on the upper end portion, A screw thread is formed to form a structure in which the second fastening portion 113 protruding downward is provided at the lower end portion. In the present embodiment, in consideration of the ease of forming parts, manufacturing cost, etc., after the main body 110 is manufactured separately from the first main body 110a and the second main body 110b, separate fastening members such as bolts and screws are used. They were assembled to each other through, but if necessary, they may be integrated into one piece or separately assembled into three or more parts, or three or more separately manufactured parts may be assembled into one.

The pressure member 120 has a gas inflow line 121a for guiding the injected gas supplied from the outside into the measurement object P and a gas outflow line 121b for guiding the gas inside the measurement object to the outside. , The first fastening portion 122 is provided with a thread formed on the outer peripheral surface, the sealing ring seating groove 123 is formed on the outer peripheral surface of the lower end, the sealing ring seating groove 123 is tapered so that its outer diameter is downward It gradually expands downwards, and is provided with a second fastening portion 124 for installing the pressure sensor 20 at an upper end thereof, and is inserted into the guide hole 111 of the main body 110 so as to be reciprocated in the vertical direction. The first fastening part 122 is threadedly coupled to the first fastening part 112 of the main body 110, and a lower end portion including the sealing ring seating recess 123 is exposed downward of the main body 110 so that the second fastening part 122 is exposed to the second fastening part. It forms a structure disposed inside the fastening portion 113.

The sealing ring S1 is inserted into the sealing ring seating groove 123 while surrounding the pressing member 120, and together with the lower end of the pressing member 120 exposed downward of the main body 110, to the outside. It is inserted into the neck of the opened measuring object P.

The pair of locking members (130, 130 '), the cross-sectional shape is formed in a semi-circular shape, the locking jaw 131 is formed on the lower end of the engaging projection (P1) of the neck (P1) of the measuring object (P), the thread on the outer peripheral surface The formed fastening part 132 is provided at the upper end, and the fastening part 132 is screwed to the second fastening part 113 of the main body 110 in a state where the fastening part 132 is surrounded by the butt part of the neck of the workpiece P. do.

In the present embodiment, the sealing ring (S2) is installed in the main body 110, the sealing ring (S2) to maintain the airtight between the main body 110 and the neck of the measuring object (P), in this case In addition, the leakage of the pressure medium into the gap between the body 110 and the neck of the measurement object P is doubled, so that the sealing function is further improved. Here, the reference numeral "114" is a reinforcing ring fixing part formed in the main body 110, and the sealing ring S2 is inserted into and fixed to the reinforcing ring fixing part 114.

In addition, a separate sealing ring S3 is inserted into the guide hole 111 to surround the outer circumferential surface of the pressing member 120, and the sealing ring S3 is disposed between the main body 110 and the pressing member 120. Confidentiality was kept. In this case, the leakage of the pressure medium into the gap between the main body 110 and the pressing member 120 by the sealing ring (S3) is doubled to have the advantage that the sealing function is further improved.

In addition, as shown in Figure 3, the pair of locking members (130, 130 ') are accurately matched with each other via the locking member connecting pin 140 to surround the neck of the workpiece (P). In this case, the pair of engaging members 130 and 130 'are easily brought into contact with each other, and the engaging members 130 and 130' can be precisely matched with each other, so that the assembling of the members for the internal pressure measurement is considerably easier. There is an advantage.

On the other hand, as shown in Figures 1 to 4, by keeping the outer diameter of the portion located below the sealing ring seating groove 123 of the pressing member 120 in a downward direction, the sealing ring (S1) is Only the outer diameter of the pressing member 120 positioned below the sealing ring seating groove 123 was to be opened in the outward direction. In this case, while changing the measured object P in a state in which the experimental environment is kept constant. Even if the internal pressure measurement is performed repeatedly, there is an effect that the bottleneck is always kept tight every time.

Referring to Figures 1 to 4 the operating state of the pressure-resistant measuring apparatus according to the present invention are as follows.

First, while engaging the locking jaw 131 of each of the locking members (130,130 ') over the protrusion (P1) of the measurement object (P), the locking member (130,130') to each other, and then the first of the main body 110 By screwing the two fastening portions 113 and the fastening portions 132 of the pair of engaging members 130 and 130'butted with each other, as shown in FIG. 4, the upper end of the neck of the measurement object P is the main body. While being in close contact with 110, the lower end of the pressing member 120 exposed downward of the main body 110 and the sealing ring S1 are both inserted into the neck of the measurement object P.

Thereafter, when the pressing member 120 is rotated counterclockwise (clockwise in the case of a left screw) to move the pressing member 120 upward, the sealing ring S1 is tapered of the sealing ring seating groove 123. The surface is opened in the outward direction based on the axial center, and the gap between the inner peripheral surface of the neck portion of the measurement object P and the outer peripheral surface of the pressing member 120 is sealed.

In such a state, when the gas line is opened by turning the handle 81 of the gas supply control mechanism 80, the CO 2 gas from the injection gas supply source 70 passes through the gas supply control mechanism 80 of the pressure member 120. It is supplied to the gas inflow line 121a and flows into the measurement object P. At this time, the gas discharge control mechanism 90 maintains the closed state.

Subsequently, when the CO 2 gas is introduced into the measurement object P and the internal pressure of the measurement object P is maintained at a high pressure state, the gas discharge control mechanism 90 is opened while the gas supply control mechanism 80 is opened. By pressing the push part 91 to be opened, the internal gas of the measurement object P is discharged to the gas outlet line 121b to be discharged to the outside through the gas discharge control mechanism 90. As such, when the gas discharge control mechanism 90 is opened for an appropriate time in the state in which the gas supply control mechanism 80 is opened, the inside of the measurement object P is filled with only CO2 gas, so that the characteristics of the measurement object P It is possible to effectively carry out the measurement of the internal pressure change for the purpose of identification.

Thereafter, while the gas supply control mechanism 80 and the gas discharge control mechanism 90 are closed, the input unit 50 is operated so that the measured object P may elapse over time by the pressure sensor 20. The internal pressure change is measured, and the internal temperature change of the chamber 10 by the temperature sensor 30, that is, the ambient temperature change of the measurement object P is measured.

When the measurement work of the measurement object P is completed, only the gas discharge control mechanism 90 is opened while the gas supply control mechanism 80 is closed, so that the internal gas of the measurement object P is discharged to the outside, The measurement object holding mechanism 100 is separated from the measurement object P and taken out from the chamber 10.

According to the present invention, since the injection gas can be injected into the measurement object P at an appropriate pressure by simple operation of the gas supply control mechanism 80 and the gas discharge mechanism 90, the experiment work becomes very convenient.

In addition, since the gas supply control mechanism 80 and the gas discharge mechanism 90 can be adjusted appropriately to fill the injection gas in the concentration of the inside of the measuring object P, a pressure-resistant measurement experiment for determining the characteristics of the plastic container is performed. It will be more effective and faster.

On the other hand, when the injection gas is a relatively heavy CO2 gas, as shown in Figures 1 and 4, the auxiliary gas line 150 to the gas inlet line 121a of the measurement hermetic holding mechanism 100 It is preferable to connect the, so that the outlet of the auxiliary gas line 150 is disposed on the bottom of the measurement object (P). As such, when the auxiliary gas line 150 is used, the injected CO 2 gas is drawn up from the bottom of the measurement object P, so that the atmosphere filled in the measurement object P at the time of CO 2 gas injection is discharged. ) Can be discharged to the outside faster.

In addition, as shown in FIG. 5, the gas supply control mechanism 80 and the gas discharge control mechanism 90 are applied as solenoid valves which are operated and controlled by the main control unit 40, so that the injected gas is measured ( It is also possible to automate the operation of injecting or discharging P). In the present embodiment, both the gas supply control mechanism 80 and the gas discharge control mechanism 90 are applied as solenoid valves, but only one of the gas supply control mechanism 80 or the gas discharge control mechanism 90 is solenoid valve. Of course, it can also be applied to.

The present invention is not limited to the embodiment as described above, and may be modified in various ways without departing from the scope of the following claims.

For example, as shown in FIG. 1 or FIG. 5, the humidity sensor HS measuring the humidity inside the chamber 10 may be reinforced to test the correlation between the humidity and the internal pressure change of the measuring object P. It may be.

In addition, the present invention is not limited to the measurement of the internal pressure of the specific measurement object (P), of course, the injection gas can also be variously applied as necessary.

According to the present invention as described above, since the injection gas can be injected into the inside of the measuring object P at a suitable pressure with a simple operation of the gas supply control mechanism 80 and the gas discharge mechanism 90, the experimental work is performed. It is very convenient, and the gas supply control mechanism 80 and the gas discharge mechanism 90 can be adjusted appropriately to fill the injection gas in a high concentration inside the measurement object P, so that it is possible to measure the pressure resistance for understanding the characteristics of the plastic container. The effect is to make the experiment more efficient and faster.

Claims (3)

A chamber 10 forming a sealed space; A measured object hermetic holding mechanism 100 disposed inside the chamber 10 to seal the measured object P; A pressure sensor 20 installed in the measurement object airtight holding mechanism 100 to measure the internal pressure of the measurement object P; A temperature sensor 30 for measuring the internal temperature of the chamber 10; A main control unit 40 which receives the output signals from the pressure sensor 20 and the temperature sensor 30 and processes the internal pressure change of the measurement data and stores the data; An input unit 50 for controlling the operation of the main control unit 40; In the pressure-resistant measuring device having an output unit 60 that is operationally controlled by the main control unit 40 to output the experimental results to the outside, The gas inlet line 121a for guiding the injected gas supplied from the outside to the measurement object hermetic holding device 100 into the measurement object P and the gas outlet line 121b for guiding the gas inside the measurement object to the outside are provided. On the other hand, the injection gas supply source 70 for supplying the injection gas to the gas inlet line 121a of the measurement object hermetic holding mechanism 100; A gas supply control mechanism 80 for controlling the injection gas supply from the injection gas supply source 70 to the gas inlet line 121a; Pressure measurement apparatus characterized in that the gas discharge control mechanism 90 for controlling the discharge of the gas inside the measurement object from the gas outlet line (121b) of the measurement object airtight mechanism 100 to the outside is reinforced. According to claim 1, wherein the auxiliary gas line 150 is connected to the gas inlet line (121a) of the measurement object airtight mechanism 100, the outlet of the auxiliary gas line 150 is the bottom portion of the measurement object (P) Pressure resistance measuring device, characterized in that disposed in. The pressure resistance measuring device according to claim 1, wherein at least one of the gas supply control mechanism (80) and the gas discharge control mechanism (90) is a solenoid valve operated by the main control unit (40).

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