KR100832109B1 - An apparatus for measuring the degree of vacuum in the products - Google Patents

Abstract

An apparatus for measuring the degree of vacuum inside products is provided to improve measure measurement accuracy at low cost by adding several simple elements to a conventional measuring apparatus. An apparatus for measuring the degree of vacuum inside a product includes a nipple(90), a sub hose(100), and a centering(110). The nipple is connected to an inlet of a vacuum sensor(60) and is a coupling unit connecting the vacuum sensor and the sub hose with airtight. The sub hose is inserted in a vacuum hose(30) and extended near a socket coupler(40). The socket coupler is coupled to a plug coupler(50). The plug coupler is a coolant pipe(55) for measuring the degree of vacuum accurately at most. The centering is coupled to an end of the sub hose for locating the sub hose at an inside center of the vacuum hose and shields foreign substance from the end of the sub hose.

Description

An apparatus for measuring the degree of vacuum in the products}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum degree measuring method or a vacuum degree measuring device, and more particularly, to a method and apparatus for more accurately measuring the degree of vacuum of a product (ex. A refrigerator, etc.), specifically, the degree of vacuum inside a refrigerant pipe in a product.

In order to inject the compressed refrigerant into the product, the vacuum degree inside the refrigerant pipe located in the product must satisfy a certain value. For this purpose, the vacuum degree of the product is measured.

1 is a schematic view for explaining a method of measuring the degree of vacuum of a conventionally performed product.

Referring to FIG. 1, a refrigerant pipe 55 is installed at one side of a product (for example, a refrigerator), and the refrigerant pipe 55 is a pipe in which a refrigerant is stored, and removes air and various foreign matters inside the refrigerant pipe. The vacuum level is measured while making the vacuum state. One side of the refrigerant pipe 55 is provided with a plug coupler (plug coupler) 50 to be connected to the outside.

Referring to the general vacuum measuring apparatus for measuring the vacuum degree of the product, the suction filter 20 is formed on one side of the vacuum pump 10. The vacuum pump 10 is used as a driving source for evacuating the inside of the refrigerant pipe in the product. One side of the suction filter 20 is provided with a vacuum sensor 60 for measuring the degree of vacuum. The degree of vacuum measured by the vacuum sensor 60 is improved by the vacuum gauge 70 connected with the vacuum sensor. That is displayed. The vacuum gauge 70 is mechanical or electronic. The control panel 80 is electrically connected to the vacuum gauge 70, the control panel 80 serves to control the entire vacuum measuring device. The suction filter 20 is connected to penetrate the vacuum hose 30, and the other end of the vacuum hose 30 is provided with a socket coupler 40. The socket coupler 40 is fastened to the plug coupler 50 connected to the refrigerant pipe 55 in the product.

A method of measuring a vacuum degree using the vacuum degree measuring apparatus of the product shown in FIG. 1 will be described.

First, the socket coupler 40 formed at the end of the vacuum hose 30 is fastened / connected to the plug coupler 50 connected to the refrigerant pipe 55 of the product. Tighten tightly to prevent air tightness. In this state, the vacuum pump 10 is driven. By the operation of the vacuum pump 10, the space inside the product, that is, not yet vacuumed and inside the refrigerant pipe containing air and various foreign matters is vacuumed. As the air and various foreign matters inside the refrigerant pipe of the product are absorbed through the vacuum hose 30 and the suction filter 20, the inside of the product is evacuated.

At this time, the vacuum sensor 60 mounted on the upper end of the suction filter 20 reads the real-time vacuum degree and transmits the signal to the vacuum gauge 70 mounted on the control panel 80, to the vacuum gauge 70. The degree of vacuum is displayed in real time.

This conventional approach requires that the vacuum sensor 60 be measured and displayed on the vacuum gauge 70 because the vacuum sensor 60 is located close to the vacuum pump 10 and is far from the product due to the configuration requirements of the system. The degree of vacuum was hard to indicate the degree of vacuum of the actual product.

Therefore, there is a need for a method of measuring the vacuum degree of a product more accurately.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a method or apparatus for more accurately measuring the degree of vacuum of a product.

Another object of the present invention is to provide a device for measuring the degree of vacuum accurately of a product by simply and simply changing an existing device.

The present invention has been made to achieve the above object, the vacuum degree measuring apparatus of the present invention is a vacuum pump 10, the suction filter 20 connected to the vacuum pump, the vacuum sensor 60 formed on one side of the suction filter A socket coupler 40 formed at the other side of the vacuum hose and connected to a plug coupler connected to a refrigerant pipe in the product; and a vacuum gauge 70 connected to the vacuum sensor, a vacuum hose 30 connected to the suction filter, and a vacuum coupler connected to the refrigerant pipe in the product. In the vacuum degree measuring device for measuring the degree of vacuum inside the refrigerant pipe in the product,

A nipple (90, nipple) connected to the inlet side of the vacuum sensor, an auxiliary hose (100) connected to the nipple and inserted into the vacuum hose, and installed at the other end of the auxiliary hose to provide an end of the auxiliary hose. And a centering (110) positioned at the inner center of the vacuum hose, wherein the position of the centering is located near the socket coupler such that the auxiliary hose is connected to the vicinity of the socket coupler.

Preferably, the centering has a shape of a cylindrical tube having an empty center, and the auxiliary hose is located at an empty central portion of the cylindrical tube. More preferably, the centering has a structure having a two-stage cylindrical tube of an inner cylindrical tube and an outer cylindrical tube, and has an empty configuration such that the auxiliary hose is inserted into the center of the inner cylindrical tube.

The vacuum degree measuring apparatus of the present invention has an advantage of measuring the vacuum degree of the product more accurately since the part detected by the vacuum sensor is the end of the auxiliary hose inserted into the vacuum hose, and the part is located closer to the product. .

In addition, the present invention uses the conventional apparatus as it is, and adds only a few simple components to implement the vacuum measuring apparatus, there is an advantage that can accurately measure the vacuum degree of the product without expensive.

Hereinafter, with reference to the accompanying drawings, it will be described in more detail the vacuum degree measuring apparatus of the present invention.

2 is a schematic view for explaining a method of measuring the degree of vacuum of the product, according to a preferred embodiment of the present invention.

Referring to FIG. 2, a nipple 90, an auxiliary hose 100, and a centering 110 are included to distinguish the conventional vacuum measuring apparatus.

The nipple 90 is connected to the inlet side of the vacuum sensor 60, and the auxiliary hose 100 is connected thereto again. The nipple 90 will be referred to as a fastening means for connecting the auxiliary hose 100 and the vacuum sensor 60. Of course, the connection between the vacuum sensor 60 and the auxiliary hose 100 should be fastened so that airtightness does not occur.

The auxiliary hose 100 is inserted into the vacuum hose 30 and extends to the vicinity of the socket coupler 40 which is fastened to the plug coupler 50 connected to the refrigerant pipe 55 in the product. This is to measure the vacuum degree of the product as accurately as possible to get as close to the refrigerant pipe side of the product as possible.

The end of the auxiliary hose 100 is fastened to the center ring 110 for positioning the auxiliary hose 100 in the inner center of the vacuum hose. The center ring 110 is to prevent the end of the auxiliary hose 100 from contacting oil, foreign substances, etc., and is installed to measure the degree of vacuum more accurately. By installing the centering 110, the end of the auxiliary hose 100 can always be positioned in the center of the vacuum hose 30.

The process of measuring the vacuum degree using the vacuum degree measuring apparatus of the present invention will be described.

First, as in the conventional method, the socket coupler 40 formed at the end of the vacuum hose 30 is fastened / connected so that airtight is not generated in the plug coupler 50 connected to the refrigerant pipe 55 of the product. When the vacuum pump 10 is driven in this state, the vacuum pump 10 lowers the vacuum degree of the product while vacuuming the inside of the product through the vacuum hose 30 and the suction filter 20.

At this time, the vacuum sensor 60 mounted on the upper end of the suction filter 20 reads the real-time vacuum degree and transmits the signal to the vacuum gauge 70 mounted on the control panel 80, to the vacuum gauge 70. The degree of vacuum is displayed in real time. The vacuum sensor 60 is connected to the nipple 90, the nipple 90 is connected to the auxiliary hose 100, the auxiliary hose 100 to the vicinity of the socket coupler (40) closest to the product Since the connection is installed, the point where the vacuum sensor 60 reads the degree of vacuum is able to read the point closest to the product side.

On the other hand, the end of the auxiliary hose 100 is not in contact with the vacuum hose 30 by the center ring 110, but is located in the center of the vacuum hose 30, there is no risk of contact with oil, foreign matter, etc., more accurately The degree of vacuum can be measured.

In order to place the end of the auxiliary hose 100 in the center of the vacuum hose 30, the shape of the centering 110 has a shape of a cylindrical tube with an empty center, and the auxiliary hose 110 is formed at an empty center of the cylindrical tube. It will have a structure that is located.

Next, the shape of the centering according to the preferred embodiment will be described.

3 is a cross-sectional view taken along the line A-A of FIG. 2, showing the shape of the centering 110, according to one preferred embodiment.

Referring to Figure 3, the center ring 110 is a structure having a cylindrical tube of two stages of the inner cylindrical tube and the outer cylindrical tube, the hollow of the auxiliary hose 100 is inserted into the center of the inner cylindrical tube, that is, the cavity To form a structure. An auxiliary hose 100 is inserted into the cavity. Accordingly, the end of the auxiliary hose 100 is to be located in the center of the vacuum hose 30.

Hereinafter, an experimental example in which the vacuum degree is measured by implementing the prior art of FIG. 1 and the present invention of FIG. 2 will be described.

Experimental Example

The vacuum degree was measured by configuring a vacuum degree measuring apparatus as shown in FIG. 1, and the vacuum degree was measured by configuring a vacuum degree measuring apparatus as shown in FIG. The product used for the two experiments was an LG refrigerator (capacity: 500L), and a vacuum pump (TRP36, dominant vacuum technology) (emission volume of 600L per minute) was used. After the vacuum pump was turned on, the vacuum value stabilized after 10 minutes. The vacuum value was measured, respectively. The results are shown in Table 1.

Table 1. Vacuum Measures

division Configuration Vacuum measure (Torr) Remarks Prior art 1 0.03 The present invention 2 0.32

As can be seen from the diagram, in the prior art, since the area detected by the vacuum sensor is inside the suction filter located on the vacuum pump side, the value of the degree of vacuum is measured relatively low. Since the end of the auxiliary hose inserted inside the center, that is, the portion where the centering is located, the vacuum value was measured higher. From the above test results, it can be seen that the vacuum degree measuring device of the present invention can measure the vacuum degree of the product more accurately because the part detected by the vacuum sensor is closer to the product.

The above description is a specific embodiment of the present invention, the technical idea of the present invention is not limited to the above embodiment, will be described in detail in the claims to be described later.

The inventive concepts and embodiments disclosed herein can be used by those skilled in the art as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. In addition, such modifications or altered equivalent structures made by those skilled in the art may be variously changed, substituted, and changed without departing from the scope of the technical idea described in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram for explaining a method of measuring a degree of vacuum of a product generally performed in the related art.

Figure 2 is a schematic diagram for explaining the manner of measuring the degree of vacuum of the product, according to a preferred embodiment of the present invention.

3 is a cross-sectional view taken along the line A-A of FIG.

* Description of the symbols for the main parts of the drawings *

10: vacuum pump

20: suction filter

30: vacuum hose

40: socket coupler

50: plug coupler

55: refrigerant piping

60: vacuum sensor

70: vacuum gauge

80: control panel

90: nipple

100: auxiliary hose

110: centering

Claims (4)

A vacuum pump 10, a suction filter 20 connected to the vacuum pump, a vacuum sensor 60 formed at one side of the suction filter, a vacuum gauge 70 connected to the vacuum sensor, and a vacuum hose 30 connected to the suction filter. And a socket coupler 40 formed on the other side of the vacuum hose and fastened to a plug coupler connected to the refrigerant pipe in the product, the vacuum degree measuring device measuring a vacuum degree in the refrigerant pipe in the product, A nipple (90, nipple) connected to the inlet side of the vacuum sensor, an auxiliary hose (100) connected to the nipple and inserted into the vacuum hose, and installed at the other end of the auxiliary hose to vacuum the end of the auxiliary hose. Including a centering (110) positioned in the inner center of the hose, The position of the centering is located near the socket coupler, the auxiliary hose is connected to the vicinity of the socket coupler vacuum degree measuring apparatus. The method of claim 1, The centering device has a shape of a hollow cylindrical tube having a central portion, and the auxiliary hose is positioned in the empty central portion of the cylindrical tube. The method of claim 1, The centering is a structure having a two-stage cylindrical tube of the inner cylindrical tube and the outer cylindrical tube, the vacuum degree measuring apparatus, characterized in that the auxiliary hose (100) is empty so as to be inserted into the center of the inner cylindrical tube. delete

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