JP3071653U - Composite valve for refrigerant equipment - Google Patents

Abstract

(57) [Abstract] [Problem] At the time of piping work, it is difficult for foreign matter to enter the piping, and it is possible to reduce the possibility of clogging of the piping, so that the installation area can be reduced, and the number of parts is small and the cost is low. The present invention provides a composite valve for a refrigerant facility which can be manufactured by the above method. The apparatus includes a valve body, an opening / closing valve, a refrigerant inlet, a moisture detector, a fluid indicator, and a tap. The valve body 2 includes a flow path 21 formed inside the pipe 20 in a circular cross section and a valve housing 4.
And a detector storage unit 9. Then, when mounting to the refrigerant equipment, simply connect both sides of the flow path 21 to the pipe of the refrigerant equipment, and open and close the valve 3, the refrigerant inlet 5, the fluid indicator 7, and the moisture detector 6 in the pipe of the refrigerant equipment. Can be arranged.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to an improvement of a valve for a refrigerant facility used in a refrigerant facility such as an air conditioner or a refrigerator.

[0002]

[Prior art]

 For example, in product installation work for air conditioners, after connecting the outdoor unit and the indoor unit with piping, the vacuum pump is used to remove air in the piping, so-called vacuuming, and then the fluorocarbon gas sealed in the outdoor unit Flow through the pipes and circulate from the outdoor unit to the indoor unit.However, during this evacuation, a valve is provided to prevent the refrigerant from flowing into the pipes, and the valve is closed. Then, the valve is opened to allow the refrigerant to flow through the piping. In the piping connecting the outdoor unit and the indoor unit, there is a refrigerant inlet for injecting refrigerant, a fluid indicator for checking the flow of refrigerant in the flow path, and a moisture detector for checking the amount of water in the flow path. Conventionally, such pipe parts are connected to the pipes by screw connection or brazing at the time of product installation work in an air conditioner. However, since these are connected to the pipe by screw connection or brazing, foreign matter such as processing powder generated by screw processing or oxide scale generated by brazing enters the pipe, and as a result, May cause clogging. In addition, since a large number of pipe parts are connected, it is necessary to take up a lot of installation space, and it takes time for piping work. In addition, joining parts are required when connecting each piping part to the piping, which increases the number of parts and increases production costs. In addition, it is necessary to separately manage the ordering of each piping part, and shipping costs etc. are added to each piping part, resulting in high costs.

[0003]

[Problems to be solved by the invention]

 The invention of the present application has been proposed in view of the above-mentioned circumstances, and in piping work, foreign matters are hard to enter the piping and the possibility of clogging of the piping can be reduced, so that the installation area can be reduced, and Another object of the present invention is to provide a composite valve for cooling equipment which can be manufactured at low cost with a small number of parts.

[0004]

[Means for Solving the Problems]

 The present invention solves the above-mentioned problems by providing a composite valve for refrigerant equipment having the following features. The first invention of the present application is provided with a flow path 21 for flowing a fluid, the flow path 21 is provided with an opening / closing valve 3 for opening and closing the flow path 21, and a refrigerant injection port 5 for injecting a refrigerant into the flow path 21. A water detector 6 for checking the amount of water in the flow path 21 and a fluid indicator 7 for checking the flow of the refrigerant in the flow path 21 are provided. Then, at the time of attachment to the refrigerant equipment, both ends of the flow path 21 are connected to pipes provided in the refrigerant equipment.

According to the second invention of the present application, one end of the flow path 21 according to the first invention of the present application forms a receiving port 22a for receiving a fluid, and the other end of the flow path 21 forms an outlet 22b for sending out a fluid. What does it do? The opening / closing valve 3 is provided between the receiving port 22 a and the outlet 22 b in the flow path 21, and between the receiving port 22 a and the opening / closing valve 3, the refrigerant inlet 5, the moisture detector 6, A fluid indicator 7 is provided.

[0006] The third invention of the present application is that the refrigerant flows between the outlet 22b and the opening / closing valve 3 in the flow path 21 according to the first or second invention of the present invention, and the refrigerant flows into the flow path 21 as the temperature of the refrigerant rises. A stopper 8 is provided to be discharged outside the container.

[0007] In the present invention configured as described above, when attaching to the refrigerant equipment, both sides of the flow path 21 may be connected to the piping of the refrigerant equipment. 3 and the coolant inlet 5, the fluid indicator 7, and the moisture detector 6 can be arranged, and the coolant inlet 5, the fluid indicator 7, the moisture detector 6, and the like are separately provided as in the related art. Installation work can be performed in a short time and in a narrow place compared to when connecting. In addition, it is not necessary to connect them by screwing or brazing as in the past when piping, which prevents the generation of foreign substances such as processing powder generated by screw processing and oxide scale generated by brazing. This can prevent the piping from clogging. In addition, since the refrigerant injection port 5, the fluid indicator 7, and the moisture detector 6 are provided together with the opening / closing valve 3, it is possible to eliminate the need for connecting parts for connecting these to the piping of the refrigerant equipment as in the related art. In addition, the number of parts can be reduced and the size can be reduced. Therefore, it can be installed in a narrow place and can be manufactured at low cost.

[0008]

[Embodiment of the invention]

 Hereinafter, a valve for a refrigerant facility according to an embodiment of the present invention will be specifically described with reference to the drawings. FIG. 1 is a front view of a refrigerant equipment valve according to an embodiment of the present invention, FIG. 2 is a right side view thereof, FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1, and FIG. FIG. 4 is a sectional view taken along line IV-IV.

The composite valve 1 for refrigerant equipment of the present invention includes a valve body 2, an opening / closing valve 3, a cooling medium inlet 5, a moisture detector 6, a fluid indicator 7, and a melting plug 8. Have.

The valve main body 2 includes a flow path 21, which is formed into a circular cross section by a pipe 20, a valve housing 4, and a detector housing 9.

The flow path 21 is for flowing a fluid, and is provided with an opening / closing port 24 for opening / closing the flow path 21 by the opening / closing valve 3 in the upper and lower central portion of FIG. The opening 24 causes the flow path 21 to form a first flow path 22 on the front side (lower side in the figure) of the opening / closing opening 24 and a second path linearly extending rearward (upper side in the figure) from the first flow path 22. It is divided into a flow path 23. In this embodiment, the fluid is set to flow from the first channel 22 to the second channel 23. Therefore, in the valve 1 of the present embodiment, the flow direction of the fluid in the flow path 21 is formed from the first flow path 22 to the second flow path 23 (X direction in the drawing), and the front end side of the first flow path 22 is The second flow path 23 is connected to the piping of the refrigerant equipment such that the receiving port 22a for receiving the fluid is formed, and the rear end side of the second flow path 23 forms the outlet 23a for sending out the fluid.

The valve storage section 4 is for storing a spindle 31 of the opening / closing valve 3 described later, has a tubular shape, has a storage hole 41 therein, and can store the spindle 31 in the storage hole 41. Has been made. The lower end of the storage hole 41 is opened so as to communicate with the opening / closing port 24 in the flow path 21, and an entrance 42 through which the tip of the stored spindle 31 is inserted into and out of the opening / closing port 24 in the flow path 21. No. The upper side of the storage hole 41 extends at an angle A of approximately 45 ° with the axial direction of the flow path 21 and extends upward at a predetermined length. The upper end is opened to form an operation port 43 for operating the stored spindle 31. The operation port 43 is formed to have a smaller diameter than the storage hole 41 after the spindle 31 is stored in the storage hole 41, so that the stored spindle 31 does not fall out of the operation port 43. On the other hand, an inner thread portion 44 is provided on the inner peripheral wall on the lower side of the storage hole 41 so that the spindle 31 can be screwed therein.

The detector storage section 9 is for storing the moisture detector 6 and is formed in the first flow path 22. The detector housing 9 in the present embodiment is formed of a cylindrical body separate from the tube of the valve body 2, is arranged so that the axial direction is oriented in the front-rear direction, and has a rear peripheral wall and a front peripheral wall. The pipe 20 of the valve body 2 is connected to both sides of the peripheral wall of the valve body by brazing, so that the inside of the detector housing 9 communicates with the pipe of the valve body 2 and the first flow path 22.

A main body mounting portion 91 is provided at a lower end side of the detector housing portion 9. The main body mounting portion 91 is for fixing the valve main body 2 to another member. In the present embodiment, as shown in FIG. 1 and FIG. The projecting portions are provided with bolt mounting screws 92, 92, and the valve body 2 is fixed to other members via the bolt mounting screws 92, 92.

As shown in FIG. 3, the opening / closing valve 3 includes a spindle 31 housed in the valve housing 4 of the valve body 2 and a valve seat 36 formed in the valve body 2. The spindle 31 forms a valve body, has a columnar shape large enough to be stored in the valve storage section 4, and has a screw portion 32 for screwing the main body on the lower side on the outer periphery. A ring-fitting groove 33 is provided on the upper side of the flange portion 32, and the O-ring 33a is fitted into the ring-fitting groove 33. At the lower end of the spindle 31, there is provided a closing part 34 having a plane perpendicular to the axial direction of the spindle 31 for closing the opening / closing port 24 of the first flow path 22 in the valve body 2. The upper end of the spindle 31 is provided with a tool engagement hole 35 for engaging the tool.

After the O-ring 33 a is inserted into the ring-fitting groove 33, the spindle 31 having the above-described structure is inserted into the storage hole 41 of the valve storage unit 4. The main body screw portion 32 is housed in the portion 44 so as to be screwed therein, and is guided by the inner screw portion 44 of the housing hole 41 and moves along the axial direction of the housing hole 41. This movement causes the closing portion 34 of the spindle 31 to protrude from the storage hole 41 to the opening / closing port 24 in the flow path 21 as shown in FIG. 5 and move from the opening / closing port 24 into the storage hole 41. Also, during this movement, the O-ring 33a fitted in the ring fitting groove 33 moves while sliding on the inner wall surface of the storage hole 41, so that the entrance and exit 42 of the storage hole 41 and the operation port 43 are moved. Is maintained in a closed state. After the spindle 31 is stored in the storage hole 41, the bag-shaped protection cap 45 is screwed into the valve storage section 4, so that the spindle 31 is protected.

The valve seat 36 is for bringing the closing portion 34 of the spindle 31 into contact with the valve seat 36. By bringing the closing portion 34 of the spindle 31 into contact with the valve seat 36, the closing portion 34 of the spindle 31 is brought into contact with the valve body 2. The opening / closing port 24 of the flow path 21 in FIG. The valve seat 36 extends from the lower end of the storage hole 41 of the valve main body 2 to the inner wall surface of the valve main body 2 in which the opening / closing port 24 of the flow path 21 is formed. The portion is formed in a circular shape so that the closing portion 34 of the spindle 31 housed in the housing hole 41 can abut over the entire circumference. In the present embodiment, the portion of the valve seat 36 on the storage hole 41 side (lower left portion in FIG. 3) is formed at the boundary between the storage hole 41 and the flow channel 21, while the portion on the flow channel 21 side ( 3 is provided on a projection 71 projecting radially inward from the inner wall surface of the valve body 2. The projecting portion 71 is formed on the inner wall surface of the valve body 2 at a predetermined length substantially along the circumferential direction, and includes a first side surface 71a on the lower side in the figure facing the first flow path 22 and a second flow path. 23 and a second side surface 71b on the upper side in the figure, which forms a substantially right-angled triangular cross section. Further, the first side surface 71a is gradually inclined upward in the figure from the base end 71c on the inner wall surface side of the valve main body 2 to the front end 71d, and with respect to the fluid flow direction (X direction in the drawing) of the flow path 22. The second flow path 23 has an inclined surface inclined at about 45 °. The projection 71 thus formed is drilled from the storage hole 41 side to form a portion of the valve seat 36 on the flow path 21 side. The shape of the projection 71 is not limited to a triangular cross section, and can be changed as appropriate. However, it is preferable to form the first side surface 71a of the projection 71 on an inclined surface inclined toward the second flow path 23 in that the flow resistance of the fluid can be reduced. Also, the amount of inclination of the first side surface 71a of the projection 71 is not limited to the angle of 45 ° as described above, and may be any angle as long as it is inclined toward the second flow path 23, and is not particularly limited.

The reason why the projection 71 is provided and the valve seat 36 is formed on the projection 71 is to reduce the diameter of the spindle 31 and to make the entire valve 1 compact. More specifically, since the spindle 31 closes the flow path 21 from a direction of approximately 45 ° as in the present embodiment, when the diameter of the spindle 31 is equal to or smaller than the diameter of the flow path 21, Road 21 cannot be closed. Therefore, it is necessary to make the diameter of the spindle 31 larger than the diameter of the flow path 21. However, if the diameter is made larger than the diameter of the flow path 21, the valve housing 4 and the spindle 31 become large, and the entire valve 1 becomes compact. You will not be able to do so. Therefore, by providing the protruding portion 71, the opening / closing port 24 of the flow path 21 is made small, and the opening / closing port 24 is closed by the spindle 31 having the same or smaller diameter as the flow path 21. 1 is made compact. Therefore, the spindle 31 used in the present embodiment has a diameter equal to or smaller than the diameter of the first flow path 22. However, the present invention is not limited to the use of the spindle 31 having the same diameter as or smaller than the diameter of the first flow path 22, and a spindle 31 having a diameter larger than the diameter of the first flow path 22 may be used. Even if the projection 71 is not provided, by cutting the inner wall surface of the valve main body 2 in which the flow path 21 is formed, a concave portion having a substantially triangular cross section is formed from the inner wall surface. What is necessary is just to make a side surface function as the valve seat 36, and can be changed suitably.

The moisture detector 6 includes an indicator 6. The indicator 6 is provided at its tip with a detecting portion 61 whose color changes according to the amount of moisture. When the color of the detecting portion 61 changes, it can detect that the amount of moisture has increased. The indicator 6 is attached to a mounting hole 93 provided on the lower surface of the detector housing 9 of the valve body 2 such that the indicator 6 can be inserted into the detector housing 9 from the front end side. The part 61 is arranged in the detector housing part 9.

The fluid indicator 7 is for checking the flow of the refrigerant in the flow path 21. In the present embodiment, the fluid indicator 7 is composed of a transparent body 7 covering the front surface of the detector housing of the valve body 2. The flow of the refrigerant in the flow path 21 is confirmed by looking at the refrigerant flowing through the detector housing 9 from the outside of the valve body 2 through the transparent body 7. The transparent body 7 also functions as a viewing window for viewing the detection unit 61 of the moisture detector 6 in the detector storage unit 9.

After connecting the valve 1 to the piping of the refrigerant equipment, the refrigerant injection port 5 is used to inject and replenish the refrigerant into the piping, to evacuate the air in the piping, to remove the air in the piping, and to control the refrigerant pressure in the piping. It also plays the role of measuring. In this embodiment, as shown in FIGS. 2 and 4, the refrigerant injection port 5 includes a connection pipe 51 attached to the detector housing 9 of the valve body 2 and an annular pipe provided inside the connection pipe 51. Core 52. The lower end of the connection pipe 51 is attached to the right peripheral wall of the detector storage section by fixing means such as brazing, so that the inside of the connection pipe 51 and the interior of the detector storage section 9 communicate with each other. ing. The upper end side of the connection pipe 51 extends obliquely upward. Further, a screw portion 51a for connecting a vacuum pump is provided on the outer periphery of the upper end of the connection pipe 51, and the hose end of the vacuum pump can be connected to the screw portion 51a for connecting the vacuum pump.

The core 52 is for maintaining the inside of the connection pipe 51 in a sealed state, and when the core 52 is pressed toward the detector housing 9, the core 52 is The inside of the detector housing 9, which forms a part, communicates with the upper end opening of the connection pipe 51 so that after connection to the piping of the refrigerant facility, the connection pipe 51 can be evacuated and the refrigerant can be replenished. Has been made. A cap nut 54 is screwed into the vacuum pump connection thread 51a of the connection pipe 51. The cap nut 53 is used to protect the core 52 when not in use, and is removed when the coolant inlet 5 is used.

The tap 8 is for automatically discharging the refrigerant to the outside when the temperature of the refrigerant rises in the pipe to prevent explosion due to the temperature rise of the refrigerant in the pipe. As shown in FIG. 2, a cylindrical body 81 having a refrigerant discharge hole 82 formed of a small hole at the end is provided. The base end of the tubular body 81 is attached to the right peripheral wall on the rear side of the valve housing portion 4 of the valve body 2, so that the refrigerant discharge hole 82 and the second flow path 23 of the valve body 2 are connected. It is made to communicate. The coolant discharge hole 82 is closed in a normal state, and is opened through a fuse metal (not shown) provided in the cylindrical body 81 as the temperature rises. In the present embodiment, when the temperature of the refrigerant reaches about 75 ° C., the refrigerant discharge hole 82 is opened by the fuse metal, and the refrigerant in the second flow path 23 is automatically discharged.

Next, a method of using the composite valve 1 for a refrigerant facility of the present invention formed as described above will be described by taking as an example a case where the composite valve 1 is used for an air conditioner. For example, when the valve 1 of the present invention is used for a cooling system of a separate type (one outdoor unit and one indoor unit) as an air conditioner, the valve 1 is attached to the low-pressure gas side of the outdoor unit and used. . Specifically, as shown in FIG. 6, the cooling device 100 includes an outdoor unit 101 and an indoor unit 102, which are connected by a gas-side connection pipe 103 and a liquid-side connection pipe 104. Thus, a cooling cycle is configured.

When the outdoor unit 101 and the indoor unit 102 are installed, the protection valve 45 (shown in FIG. 3) of the valve storage unit 4 is removed from the composite valve 1 of the present invention as shown in FIG. The wrench L is engaged with the tool engagement hole 35, and the wrench L is rotated to bring the spindle 31 into contact with the valve seat 36 so that the flow path 21 is shut off. The gas-side connecting pipe 103 is connected to the receiving port 22a of the first flow path 22 of the composite valve 1 on the indoor unit 102 side, and the outlet 23a of the second flow path 23 is connected to the outdoor unit 101 side. The main body mounting portion 91 is fixed to the machine 101 or the like via bolts.

After the connection of the pipes is completed, the hose end of the vacuum pump is connected to the connection pipe 51 of the refrigerant inlet 5 of the composite valve 1 to evacuate the pipes. The spindle 31 is pulled up by rotating the wrench L engaged with the handle 31 in the opposite direction. As a result, the first flow path 22 and the second flow path 23 of the composite valve main body 1 communicate with each other (the state shown in FIG. 3). In addition, the liquid side valve 105 is opened simultaneously with the opening of the opening / closing port 24 by the spindle 31. As a result, the refrigerant gas sealed in the outdoor unit 101 flows from the first flow path 22 of the valve 1 along the second flow path 23, spreads throughout the pipes, and can be operated as a cooling cycle. Becomes Further, when the refrigerant gas flows from the first flow path 22 to the second flow path 23 of the valve 1, the refrigerant gas is linear from the first flow path 22 to the second flow path 23. The flow resistance can be reduced, and pressure loss can be prevented.

After that, the inside of the detector housing section 9 of the valve body 2 is inspected from the transparent body 7 to confirm that the color of the detecting section 61 has not changed. This makes it possible to detect that the amount of water in the pipe has not increased. At the same time, the refrigerant flowing from the transparent body 7 into the detector housing 9 is checked to check that no bubbles are generated from the refrigerant. Thereby, the amount of the refrigerant in the pipe can be confirmed. When bubbles are generated from the refrigerant, the amount of the refrigerant in the pipe is small, so the refrigerant is replenished from the refrigerant inlet 5. On the other hand, when the temperature of the refrigerant in the piping rises (75 ° C. in the present embodiment) due to the use of the refrigerant equipment, the refrigerant can be automatically discharged from the melting plug 8, and the temperature of the refrigerant increases. Explosion in piping can be prevented.

In the present embodiment, by forming the axial direction of the first flow path 22 in the flow path 21 and the axial direction of the second flow path 23 in a straight line, the flow direction of the fluid is linear. Although there is no fluid pressure loss, the present invention is not limited to this embodiment, and the angle between the axial direction of the first flow path 22 and the axial direction of the second flow path 23 is set. Can be changed as appropriate.

In this embodiment, the axial direction of the spindle 31 is arranged in a direction at an angle A of approximately 45 ° with respect to the axial direction of the linear flow path 21. However, the axial direction of the spindle 31 is not limited to this configuration, and the axial direction of the spindle 31 is arranged in a direction at an obtuse angle or an acute angle with respect to the axial direction of the first flow path 22 or the second flow path 23. It can be changed as appropriate.

In the present embodiment, the valve 1 of the present invention is used for a separate type cooling device. However, the valve 1 is widely used for an air conditioner such as a multi-type cooling device or a refrigerant device such as a refrigerator. It can be used as appropriate.

[0031]

[Effect of the invention]

 As described above, according to the invention of the present application, when mounting to the refrigerant equipment, both sides of the flow path 21 may be connected to the piping of the refrigerant equipment, and the mounting work can be performed in a short time and in a narrow place. In addition, when piping, it is not necessary to join them by screw connection or brazing as in the past, preventing the generation of foreign substances such as processing powder generated by screw processing and oxide scale generated by brazing, This can prevent clogging of the piping. In addition, since it has the refrigerant injection port 5, the fluid indicator 7, the moisture detector 6, and the melting plug 8 as well as the opening / closing valve 3, the joining parts for connecting these to the piping of the refrigerant equipment as in the prior art. Can be eliminated, the number of parts can be reduced, and the size can be reduced. Therefore, it can be installed in a narrow place and can be manufactured at low cost.

[Brief description of the drawings]

FIG. 1 is a front view of a composite valve for refrigerant equipment according to an embodiment of the present invention.

FIG. 2 is a side view of a composite valve for a refrigerant system according to an embodiment of the present invention.

FIG. 3 is a sectional view taken along line III-III in FIG. 1;

FIG. 4 is a sectional view taken along line IV-IV of FIG. 1;

FIG. 5 is a cross-sectional view of a main part in a state where a flow path is blocked by an opening / closing valve.

FIG. 6 is a system diagram of a cooling device of one embodiment using a valve for refrigerant equipment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Composite valve 2 Valve main body 3 Opening / closing valve 4 Valve accommodating part 5 Refrigerant injection port 6 Moisture detector 7 Fluid indicator 8 Tap 21 Flow path 22 First flow path 23 Second flow path 31 Spindle 103 Gas side connection pipe 104 Liquid side connection pipe

Claims (3)

[Utility model registration claims] 1. A flow path (21) for flowing a fluid, said flow path (21)
Is equipped with an on-off valve (3) for opening and closing the flow path (21), and confirms the refrigerant injection port (5) for injecting refrigerant into the flow path (21) and the amount of water in the flow path (21). Moisture detector (6)
A fluid indicator (7) for checking the flow of the refrigerant of 1) is provided, and both ends of the flow path (21) are connected to pipes provided in the refrigerant equipment when mounting the refrigerant on the refrigerant equipment. A composite valve for refrigerant equipment, characterized in that: 2. One end of a flow path (21) forms a receiving port (22a) for receiving a fluid, and the other end of the flow path (21) forms an outlet (22b) for sending out a fluid. An opening / closing valve (3) is provided between the receiving port (22a) and the outlet (22b) in the flow path (21), and the receiving port (22a) and the opening / closing valve are provided.
2. The refrigerant equipment according to claim 1, wherein a refrigerant inlet (5), a moisture detector (6), and a fluid indicator (7) are provided between the refrigerant inlet (5). Composite valve. 3. A delivery port (22b) in a flow path (21) and an opening / closing valve.
(3), the refrigerant flows through the flow path (21) with the rise in the temperature of the refrigerant.
The composite valve for a refrigerant system according to claim 1 or 2, further comprising: a melting plug (8) that is discharged outside the container.