JP3012481B2 - Refrigerant filling device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigerant charging apparatus for charging a refrigerator or the like with a refrigerant.

[0002]

2. Description of the Related Art Generally, R-22, R-
To fill a refrigerator or the like with a chlorofluorocarbon-based refrigerant such as 134a,
Refrigerant charging devices are used to charge an exact specified amount (g) of refrigerant. In addition, with the recent regulation of CFC-based refrigerants and the commercialization of small-sized and highly efficient refrigerators, the filling of refrigerants is performed with higher precision using a refrigerant charging device.

As shown in FIG. 4, a conventional refrigerant charging device 50 includes a booster pump 51 operated by compressed air,
A cylinder 52 for storing a refrigerant to be charged, a hydraulic pump 53 for pressurizing a movable piston 52a of the cylinder 52, a pulse scale 54 for measuring the position of the piston 52a, and a thermometer 55 for measuring the temperature of the refrigerant to be charged
, An automatic valve 56 operated by compressed air, and a charging control unit 57 for controlling the automatic valve 56, so that a predetermined amount of refrigerant is charged into a refrigerator or the like from a charging gun 58.

[0004] That is, the refrigerant supplied from the cylinder or the like to the refrigerant charging device 50 is pressurized by the booster pump 51 and filled in the device while maintaining the liquid state. At this time, the automatic valve 56 is in an open state, and the refrigerant is stored in the cylinder 52 in a liquid state. Then, the automatic valve 56 is closed, and the hydraulic pump 5 is closed.
In step 3, the piston 52a of the cylinder 52 is pressurized and moved, and the refrigerant in the cylinder 52 is charged into the refrigerator or the like via the charging gun 58. Here, the charging control unit 57 includes information on the cylinder shape and the temperature of the refrigerant to be charged under the pressure applied by the hydraulic pump 53.
The liquid density (g / cm ³ ) is stored, the liquid density of the refrigerant is obtained from the temperature measured by the thermometer 55, and the movement amount (volume) of the piston 52a corresponding to the weight of the refrigerant to be charged.
Is converted and set.
While monitoring the position of 2a, the piston 52 is moved to the set position.
By moving a, a set specified amount of refrigerant is accurately charged into a device such as a refrigerator.

[0005]

However, in the above-mentioned conventional refrigerant charging apparatus, the above-mentioned booster pump is required to keep the refrigerant in the refrigerant path of the apparatus in a liquid state, which makes the apparatus complicated and bulky. And expensive.

In addition, the temperature of the liquid refrigerant is measured to determine the liquid density, and the amount of movement of the piston corresponding to the amount of refrigerant charged (the weight of the refrigerant to be charged) is converted and set, so that the refrigerant is charged. Therefore, it requires many precision parts, such as an accurate thermometer, an accurate cylinder, a pulse scale that can accurately detect the amount of piston movement of the cylinder, and a hydraulic pump unit that accurately stops the piston. There is a problem that the apparatus becomes complicated, large, expensive, the environment in which the apparatus is used is restricted, and regular adjustment and maintenance are required.

Further, it is necessary to store accurate physical property data (temperature-liquid density data) of the refrigerant in the charging control section, and if a large number of types of refrigerant are to be charged, an enormous amount of data is required. Must be stored in advance.

Further, when gas refrigerant is generated in the apparatus for any reason, it is difficult to detect the gas refrigerant. If such an abnormality occurs, there is a possibility that an incorrect amount of refrigerant is charged. is there.

Furthermore, since the refrigerant weight is charged (indirectly charged) obtained by calculation, there is a trouble that the actual charged weight must always be checked.

The present invention has been made in view of the above circumstances, and uses a booster pump required in the conventional apparatus as a pressurizing means for filling, thereby simplifying the apparatus, miniaturizing the apparatus, and using an inexpensive refrigerant. The primary objective is to provide a filling device, and furthermore, the device is simplified, miniaturized, inexpensive, usable in a wide range of environmental conditions, requires only minimal adjustment and maintenance, and has a huge Quantitative charging of various types of refrigerant can be performed without storing data in advance, and it is also possible to easily detect the generation of gas refrigerant in the device, and accurately measure the actual charged weight. It is a second object of the present invention to provide a refrigerant charging device capable of performing the above.

[0011]

According to a first aspect of the present invention, there is provided a refrigerant charging apparatus for maintaining a refrigerant at a predetermined liquid pressure in a passage and maintaining the liquid refrigerant at a predetermined charging pressure or higher. In a refrigerant charging apparatus that fills equipment via an injection portion that opens in a valve, a slidable piston that partitions and forms two chambers, one chamber and the other chamber, in which the volume change per moving amount in the cylinder is equal, A liquefaction pressurizing unit that applies the set hydraulic pressure to the piston, and a filling pressurizing unit that applies the set filling pressure to the piston, and an upstream side of the one chamber
Through a check valve in a direction that allows the flow into the one chamber,
Allow flow into the other room upstream of the other room
To the refrigerant inflow side via check valves
And the outflow from the one chamber is downstream of the one chamber.
Downstream of the other chamber via a check valve in a direction that allows
Has a check valve in a direction that allows outflow from the other chamber.
Communicating with each refrigerant outlet side through said nonreturn provided downstream of the other chamber and between said other chamber and between the check valve which is provided downstream of the one chamber and one chamber above A valve that forms a passage that bypasses between the valve and a valve that allows the piston to move freely when the one chamber and the other chamber are filled with the liquefied refrigerant except when the refrigerant is filled in the device. Is provided in the bypass passage.

Further, in the refrigerant charging apparatus according to the second aspect, the refrigerant is kept in the passage as a liquefied refrigerant having a set hydraulic pressure, and the liquefied refrigerant is charged into the device via an injection section which opens at a pressure higher than the set charging pressure. In the refrigerant charging device, a slidable piston that forms two chambers, one chamber and the other chamber, having the same volume change per moving amount in the cylinder, and a liquefaction pressurizing unit that applies the set hydraulic pressure to the piston. When, and a filling pressure portion adding the set charging pressure to the piston, the one chamber above
On the upstream side, check in the direction that allows the flow into the one chamber
Via a valve, the upstream side of the other chamber is connected to the other chamber.
Refrigerant inflow through check valve in the direction that allows inflow
And the downstream side of the one chamber is
Through the check valve in the direction that allows
On the downstream side in a direction that allows outflow from the other chamber.
Each of them communicates with the refrigerant outflow side via a check valve, and is provided between the one chamber and the check valve provided downstream of the one chamber, and is provided downstream of the other chamber and the other chamber. Reverse
Forming a passage bypassing the between the stop valve, and the one chamber and the other chamber except when filling the refrigerant to the device to freely move the piston when filled with liquid refrigerant A valve is provided in the bypass passage, and a mass flow rate measuring means for measuring a mass flow rate of the liquefied refrigerant flowing through the injection section is provided upstream of the injection section. The piston is slid back and forth to pressurize the chamber on the side where the volume is reduced by the set hydraulic pressure, while the refrigerant flows into the chamber on the side where the volume is increased and the refrigerant in the path is set as described above. Keeping the liquid pressure, when the one chamber and the other chamber are filled with the liquefied refrigerant, open the valve of the bypass passage and operate the filling pressurizing unit to minimize the volume of the other chamber. Move the piston to a certain position The mass of the refrigerant to be injected into the device is set in advance, and at the time of charging the refrigerant, the valve of the bypass passage is closed, and the set refrigerant mass and the integrated value of the mass flow rate measured from the mass flow rate measurement unit are calculated. And charging control means for controlling the movement of the piston by applying the set charging pressure to the piston by the charging and pressurizing unit until the integrated value reaches the set refrigerant mass. .

[0013]

According to the first aspect of the present invention, in order to draw the refrigerant into the passage and maintain the refrigerant at the set hydraulic pressure, the refrigerant charging device according to the first aspect of the present invention closes the valve of the bypass passage and operates the liquefaction pressurizing section to operate the piston. By sliding back and forth to pressurize the chamber on the side where the volume is reduced with the above set hydraulic pressure, the refrigerant is caused to flow into the chamber on the side where the volume is increased and the refrigerant is sucked into the path by repeating this. At the same time, the refrigerant in the passage is kept at the set hydraulic pressure.
Here, the flow to the one chamber is located upstream of the one chamber.
Through the check valve in the direction that allows
On the side, there is a check valve in the direction that allows the flow into the other chamber.
And communicates with the refrigerant inflow side via
On the flow side, check the direction to allow outflow from the above one chamber
Through the valve, the other chamber is downstream from the other chamber.
Refrigerant flow through the check valve in a direction that allows the outflow of refrigerant
Since it is in communication with the outlet side , the refrigerant does not return to the chamber being sucked from the chamber on the side pressurized by the piston. Next, when the one chamber and the other chamber are filled with the liquefied refrigerant, the valve of the bypass passage is opened, and the charging and pressurizing unit is operated to liquefy the liquefied refrigerant in the other chamber with the one chamber. While moving the piston, the piston is moved to a position where the volume of the other chamber is minimized. Here, since the change in volume per movement amount of the piston is equal in the one chamber and the other chamber, the movement of the piston does not vaporize the liquefied refrigerant. Then, in order to charge the equipment with the liquefied refrigerant, the valve of the bypass passage is closed, and the set charging pressure is applied to the piston by the charging pressurizing unit. Then, the injection part opens, and the piston moves while flowing out the liquefied refrigerant in the one chamber,
The liquefied refrigerant having a mass corresponding to the volume of the piston moved toward the one chamber is charged into the device.

In the refrigerant charging apparatus according to the second aspect of the invention, in order to suck the refrigerant into the passage and maintain the liquefied refrigerant at the set hydraulic pressure, the charging control means closes the valve of the bypass passage to liquefy the refrigerant. By operating the pressure section and sliding the piston back and forth to pressurize the chamber on the side where the volume becomes smaller with the above set hydraulic pressure, the refrigerant flows into the chamber on the side where the volume becomes larger and this is repeated. The refrigerant is sucked into the passage and the refrigerant in the passage is maintained at the set hydraulic pressure. Here, the above one room
On the upstream side, check in the direction that allows the flow into the one chamber
Via a valve, the upstream side of the other chamber is connected to the other chamber.
Refrigerant inflow through check valve in the direction that allows inflow
And the downstream side of the one chamber is
Through the check valve in the direction that allows
On the downstream side in a direction that allows outflow from the other chamber.
Since the refrigerant is in communication with the refrigerant outflow side via the check valve , the refrigerant does not return to the chamber being sucked from the chamber pressurized by the piston. Next, when the one chamber and the other chamber are filled with the liquefied refrigerant, the filling control means opens the valve of the bypass passage and operates the filling pressurizing unit to liquefy the other chamber. The piston is moved to a position where the volume of the other chamber is minimized while moving the refrigerant to the one chamber. Here, since the change in volume per movement amount of the piston is equal in the one chamber and the other chamber, the movement of the piston does not vaporize the liquefied refrigerant. The filling control means is set in advance with the mass of the refrigerant to be injected into the device, and at the time of filling the refrigerant, the filling control means closes a valve of the bypass passage, and the filling pressurizing unit applies a pressure to the piston. Apply the above set filling pressure. Then, the injection part opens,
The piston is moved while the liquefied refrigerant in the one chamber flows out. Mass flow rate of the liquefied refrigerant flows out here Ru is measured by a mass flow rate measurement means. The charging control means compares the set refrigerant mass with the integrated value of the mass flow rate measured from the mass flow rate measuring means. The control unit controls the piston to move the piston toward the one chamber by applying the set filling pressure to the piston.

[0015]

Next, an embodiment of the present invention will be described with reference to the drawings. 1 to 3 show an embodiment of the present invention. FIG. 1 is an explanatory view of a refrigerant charging device, FIG. 2 is an explanatory view of a structure of a cylinder piston, and FIG. 3 is an explanatory view of a mass flow meter.

In FIG. 1, reference numeral 1 denotes a refrigerant charging device, and R-22, R-22,
A cylinder 3 of a chlorofluorocarbon-based refrigerant such as R-134a is connected.

The refrigerant inlet 2 is connected via a valve 4 and a filter 5 to a first check valve 6 and a second check valve provided in parallel with the first check valve 6 on the refrigerant path. A downstream side of the first check valve 6 communicates with a valve 7 and a piston front chamber 9 a of a cylinder 9 defined by a liquid piston 8 a of a piston 8 into two chambers. The downstream side of the check valve 7 is connected to a piston rear chamber 9 b of the cylinder 9.

Further, the piston front chamber 9a is connected to a third check valve 10, the piston rear chamber 9b is connected to a fourth check valve 11, and the third check valve 10 is connected to the third check valve 10. On the downstream side of the fourth check valve 11, a filter 12, a mass flow meter 13 as mass flow measuring means, a one-way valve 14,
It is connected via a valve 15 to a charging gun 16 as a liquefied refrigerant injection part. In addition, a path from the piston front chamber 9a to the third check valve 10 and a path from the piston rear chamber 9b to the fourth check valve 11 are bypassed. Is an automatic valve 1
7 are provided.

As shown in FIG. 2, the piston 8 is provided with a liquid piston 8a which is slid in the front and rear direction in the cylinder 9 at the front end of a rod 8c.
An air piston 8b that is slid in the front-rear direction in the air cylinder 18 is fixedly provided at the rear end of the air cylinder 18c. A shaft 8d projecting from the piston front chamber 9a is slidably provided in the rod 8c, and the shaft 8d is urged in a projecting direction by a spring 8e. That is, the shaft 8d has a cross-sectional area of the piston front chamber 9a substantially equal to a cross-sectional area of the piston rear chamber 9b, in other words, the piston front chamber 9a generated by the movement of the liquid piston 8a. And the volume change of the piston rear chamber 9b is substantially the same.

A liquefaction pressurizing section 19 and a filling pressurizing section 20 are connected to the air cylinder 18, and the liquefaction pressurizing section 19 pressurizes the compressed air by using compressed air or the like to form the air piston 8b. Is slid in the air cylinder 18 in the front-back direction, and the liquid piston 8a is slid in the cylinder 9 in the front-back direction. Here, the liquefaction pressurizing section 19 causes the inside of the cylinder 9 to be about 20 kg /
It is designed to be pressurized to a pressure of cm2.

Similarly, the filling and pressurizing section 20 is pressurized using compressed air or the like, and the air piston 8b is slid in the air cylinder 18 in the front-rear direction. It is designed to be slid in the front-rear direction inside. Here, the inside of the cylinder 9 is pressurized to a pressure of about 25 kg / cm ² by the filling pressurizing section 20.

The charging gun 16 is formed such that when the pressure applied to the inlet side valve seat becomes about 25 kg / cm ² or more, the apparatus side outlet is opened. , The refrigerant is charged into the device.

The mass flow meter 13 has a high responsiveness to a change in the flow rate so that the mass flow rate of the liquefied refrigerant at a high pressure can be accurately measured, and has a wide measurement range. As shown in (a), two flow tubes 25, 25 adjusted to the same natural frequency (inertia) and fixed at both ends, an electromagnetic oscillator 26 that applies vibration to the flow tubes 25, and a flow tube 25
And an angle detection unit 27 that detects a torsion angle θ of the flow tube 25 generated by the flow of the fluid in the inside.

That is, in this mass flow meter 13, FIG.
As shown in (b), the flow tube 25, whose ends are fixed, resonates at a natural frequency by the electromagnetic oscillator 26, and when the fluid flows through the flow tube 25, the fluid flows in the opposite directions on the inflow side and the outflow side, respectively. When the force (Coriolis force) is applied, the flow tube 25 is turned on during the half cycle of the vibration as shown in FIG.
Twisted as in (d). The torsion angle θ is proportional to the mass flow rate in the flow tube 25, and is detected as a signal proportional to the mass flow rate by the angle detectors 27 attached to both sides, so that the mass flow rate is obtained. The mass flow meter 13 is composed of two flow tubes adjusted to the same natural frequency (inertia), and detects the positional relationship between the two flow tubes. In addition, the forces experienced by the two tubes act so as to cancel each other, and the effect is extremely small. Further, in the mass flow meter 13, when gas is generated inside the pipeline, an abnormality is indicated in the value of the mass flow rate, so that it is easily determined that gas has been generated inside the pipeline.

The mass flow meter 13, one-way valve 14, automatic valve 17, liquefaction pressurizing section 19 and filling pressurizing section 20 are connected to a filling control section 21 as filling control means.

The charging control section 21 is formed so that the weight of the refrigerant to be charged can be set in advance.
Based on the signal indicating the mass flow rate inputted from 3, the integrated value of the mass flow rate is determined to determine the filling weight, and the mass flow rate and the filling weight are displayed on a display unit (not shown), and based on these values, an abnormality is determined. And the operation of the one-way valve 14, the automatic valve 17, the liquefaction pressurizing section 19, and the filling pressurizing section 20 are controlled. Further, the filling control unit 21 performs the filling in advance so that the purpose of R & D and specification of the refrigerator (refrigerant amount) and the additional inspection of the refrigerant amount by detecting an abnormality in the inspection of the production line of the refrigerator can be performed. Do not set the weight of the refrigerant
Refrigerant can be charged while monitoring the charged weight.

In FIG. 1, reference numerals 31 and 32 indicate pressure gauges for measuring the pressures in the respective pipelines, and reference numeral 33 indicates a safety valve.

Next, in the refrigerant charging apparatus having the above structure, a predetermined amount of refrigerant (for example, R-22, R-13) is supplied to equipment such as a refrigerator.
The operation at the time of charging with a CFC-based refrigerant such as 4a will be described.

First, as shown in FIG. 1, a cylinder 3 of a chlorofluorocarbon-based refrigerant is connected to a refrigerant inlet 2, and a liquefied refrigerant in the cylinder 3 is filled with a refrigerant path in the apparatus 1. 16 to the device,
When the weight of the refrigerant to be charged is set in advance and the apparatus 1 is operated, the liquefaction pressurizing section 19 is operated by the charging control section 21, and the air piston 8b of the air cylinder 18 slides back and forth, and the liquid piston of the cylinder 9 is moved. 8a is slid back and forth. At this time, the automatic valve 17
When one chamber of the cylinder 9 is in a refrigerant pressurized state, the other chamber is in a refrigerant suction state. For example, in the process in which the liquid piston 8a moves forward and pressurizes the piston front chamber 9a, the refrigerant is sucked from the cylinder 3 by the piston rear chamber 9b, and then the piston front chamber 9a is reduced to about 20 kg / cm ^2. When the liquid piston 8a is retracted by being pressurized to the pressure, the piston rear chamber 9b is pressurized. In this process, the refrigerant is sucked from the cylinder 3 into the piston front chamber 9a. This is repeated, and the piston front chamber 9a and the piston rear chamber 9b are repeated.
When the liquefied refrigerant is filled and pressurized to a pressure of about 20 kg / cm ² , the pressurization by the liquefied pressurizing unit 19 is stopped.

Next, the filling control section 21 operates the filling pressurizing section 20, moves the air piston 8b backward, and retracts the liquid piston 8a to the rearmost part. At this time, the filling control unit 21 keeps the automatic valve 17 open. Therefore, the liquefied refrigerant in the piston rear chamber 9b is moved to the piston front chamber 9a. Here, since the volume change of the piston front chamber 9a and the volume change of the piston rear chamber 9b caused by the movement of the liquid piston 8a are adjusted by the shaft 8d, the refrigerant is gasified. There is nothing to do.

Next, the filling control section 21 closes the automatic valve 17, activates the filling pressurizing section 20, moves the air piston 8b forward, moves the liquid piston 8a forward, and moves the liquid piston 8a forward. The chamber 9a is pressurized.

When the pressure becomes about 25 kg / cm ² or more, the liquefied refrigerant is charged into the device from the charging gun 16 by reducing the pressure to a predetermined pressure. The mass flow rate of the flow of the refrigerant generated at this time is measured by the mass flow meter 13, and a signal from the mass flow meter 13 is sent to the charging control unit 21, converted into a mass flow value, and Are integrated to calculate the filling weight, and these values are displayed. When the filled weight reaches the set weight, the filling control section 21 stops the filling pressurizing section 20, closes the one-way valve 14, and ends the filling of the refrigerant. When the refrigerant is charged, the piston rear chamber 9b is replenished with the refrigerant from the cylinder 3 as the liquid piston 8a moves. When filling, the mass flow meter 13
When an abnormal mass flow value is input from, this is displayed,
The filling amount up to the occurrence of the abnormality is displayed, and the filling is stopped.

Next, in order to fill another device,
The refrigerant is sucked from the cylinder 3 and the above operation is performed. An example of this operation is an example in which filling is performed by setting the filling weight in the filling control unit in advance, but it is also possible to perform filling while monitoring the filling weight without setting the filling weight in the filling control unit. It is possible.

As described above, according to this embodiment, the booster pump required in the conventional apparatus is used also as the pressurizing means for filling, so that the apparatus can be simplified and downsized. .

Further, since the mass flow rate is measured and the filling weight is directly obtained, there is no need to check the actual filling weight, which is required in the conventional apparatus.

In addition, since the mass flow is measured and the filling weight is directly obtained, if a gas refrigerant is generated in the apparatus for any reason, it is necessary to detect this from the value of the mass flow. Can be easily done.

Further, since the mass flow rate is measured, it is not necessary to store accurate physical property data (temperature-liquid density data) of the refrigerant in the apparatus in advance, and it is possible to cope with filling of various types of refrigerant. .

Furthermore, since the filling weight is measured directly instead of calculating and calculating the filling weight from various indirect parameters, many precision parts and electronic parts for calculation required in the conventional apparatus are omitted. Can simplify the equipment,
The size and cost can be reduced, and the usable environmental conditions are wide, and adjustment and maintenance can be easily performed.

In this embodiment, R-22 and R-22 are used as refrigerants.
Although the description has been given of the apparatus using the CFC-based refrigerant such as R-134a, the present invention is not limited to this.

The pressurization by the liquefaction pressurization unit and the pressurization by the filling pressurization unit are performed at about 20 kg / cm ² and about 25 kg / cm ² , respectively, based on the physical properties of R-22 and R-134a. Although it is performed under pressure, the present invention is not limited to this. Further, when a substance other than R-22 and R-134a is targeted, the above pressure values are changed according to the physical properties of the target substance. Needless to say.

In this embodiment, the mass flow meter is
The method using Coriolis force generated by the fluid flowing through the resonated flow tube has been described as an example.However, the present invention is not limited to this, and the flow rate is set so that the mass flow rate of the high-pressure liquefied refrigerant can be accurately measured. Any mass flow meter having a high response to a change and a wide measurement range may be used.

[0042]

As described above, according to the first aspect of the present invention, the booster pump required in the conventional apparatus is used also as the pressurizing means for filling, thereby simplifying and reducing the size of the apparatus. An inexpensive device can be realized.

According to the second aspect of the present invention, the booster pump required in the conventional apparatus is used also as a pressurizing means for filling, thereby achieving simplification and downsizing of the apparatus and realizing an inexpensive apparatus. In addition to the above-mentioned effects, furthermore, the equipment is simplified and downsized, it is inexpensive, the usable environmental conditions are wide, only minimal adjustment and maintenance are required, and a huge amount of data is stored in advance. It is possible to carry out constant-quantity charging of various types of refrigerants, and it is also possible to easily detect the generation of gas refrigerant in the device, and to accurately measure the actual charged weight.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a refrigerant charging device according to an embodiment of the present invention.

FIG. 2 is an explanatory view of a structure of a piston of a cylinder according to an embodiment of the present invention.

FIG. 3 is an explanatory view of a mass flow meter according to one embodiment of the present invention.

FIG. 4 is an explanatory view of a conventional refrigerant charging device.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 refrigerant filling device 3 cylinder 6 first check valve 7 second check valve 8a liquid piston 9 cylinder 9a piston front chamber 9b piston rear chamber 10 third check valve 11 fourth check valve 13 mass flow rate Total 16 Charging gun 17 Automatic valve 19 Liquefaction pressurizing unit 20 Filling pressurizing unit 21 Filling control unit

Claims (2)

(57) [Claims] 1. A refrigerant charging apparatus for maintaining a refrigerant in a passage as a liquefied refrigerant at a set hydraulic pressure and charging the liquefied refrigerant into an apparatus through an injection section that opens at a pressure equal to or higher than the set charging pressure. A slidable piston which is divided into two chambers, one chamber and the other chamber having the same change in volume per unit, a liquefaction pressurizing unit for applying the set hydraulic pressure to the piston, and the set charging pressure to the piston. And a filling pressurizing section to be added, and the upstream side of the one chamber is connected to the one chamber.
Of the other chamber through a check valve in a direction that allows
On the upstream side, a check is made to allow flow into the other chamber.
Each of the one chambers communicates with the refrigerant inflow side via a valve.
On the downstream side of the direction allowing outflow from the one chamber
The other chamber is located downstream of the other chamber via a check valve.
Each through a check valve in a direction allowing outflow from
Communicates with the medium outflow side, and between the check valve which is provided downstream of the one chamber and one chamber above, and the other chamber with the check valve which is provided downstream of the other chamber A valve that allows the piston to move freely when the one chamber and the other chamber are filled with the liquefied refrigerant except when the equipment is filled with the refrigerant. A refrigerant charging device provided in a passage. 2. A refrigerant charging apparatus for maintaining a refrigerant in a passage as a liquefied refrigerant at a set hydraulic pressure, and charging the liquefied refrigerant into equipment via an injection portion that opens at a pressure equal to or higher than the set charging pressure. A slidable piston which is divided into two chambers, one chamber and the other chamber having the same change in volume per unit, a liquefaction pressurizing unit for applying the set hydraulic pressure to the piston, and the set charging pressure to the piston. And a filling pressurizing section to be added, and the upstream side of the one chamber is connected to the one chamber.
Of the other chamber through a check valve in a direction that allows
On the upstream side, a check is made to allow flow into the other chamber.
Each of the one chambers communicates with the refrigerant inflow side via a valve.
On the downstream side of the direction allowing outflow from the one chamber
The other chamber is located downstream of the other chamber via a check valve.
Each through a check valve in a direction allowing outflow from
Communicates with the medium outflow side, and between the check valve which is provided downstream of the one chamber and one chamber above, and the other chamber with the check valve which is provided downstream of the other chamber A valve that allows the piston to move freely when the one chamber and the other chamber are filled with the liquefied refrigerant except when the equipment is filled with the refrigerant. Provided in the passage, further provided a mass flow rate measuring means for measuring the mass flow rate of the liquefied refrigerant flowing in the injection section upstream of the injection section, closing the valve of the bypass passage to operate the liquefaction pressurizing section By sliding the piston back and forth to pressurize the chamber on the side where the volume becomes smaller with the set hydraulic pressure, the refrigerant flows into the chamber on the side where the volume becomes larger and keeps the refrigerant in the path at the above set hydraulic pressure. When the one chamber and the other chamber are filled with a liquefied refrigerant, Opening the valve of the bypass passage and operating the filling pressurizing section to move the piston to a position where the volume of the other chamber is minimized, and the mass of the refrigerant to be injected into the device is set in advance, At the time of charging the refrigerant, the valve of the bypass passage is closed, and the set refrigerant mass is compared with the integrated value of the mass flow rate measured from the mass flow measuring means, and the integrated value is set to the set refrigerant. A refrigerant charging device, comprising: charging control means for controlling the piston to move by applying the set charging pressure to the piston by the charging pressurizing unit until the mass is reached.