KR20100048887A - Refrigeration air dryer - Google Patents

Abstract

PURPOSE: A cold air dryer is provided to precisely control the temperature of the compressed air of an outlet pipe using a re-heater. CONSTITUTION: A cold air dryer comprises a refrigerant system, an air system, a temperature sensor(40), a valve unit, and a temperature controller(42). The refrigerant system comprises a refrigerant compressor(10), a condenser(11), a decompression device(12), and a cooler(13). The air system comprises a re-heater(18). The temperature sensor detects the temperature of secondary air flowing in an outlet pipe. The valve unit controls the flow rate of dehumidifying air or refrigerant which flows in the re-heater of the air system. The temperature controller maintains the temperature of the secondary air by controlling the valve unit based on the temperature detected by the temperature sensor and controlling the flow rate of the dehumidifying air or refrigerant.

Description

Refrigerated Air Dryer {REFRIGERATION AIR DRYER}

The present invention relates to a refrigerated air dryer that cools compressed air to condense moisture in the compressed air to dehumidify the compressed air.

In an air pressure system using a pneumatic device such as a solenoid valve or an air cylinder, it is preferable to remove water in the compressed air in advance in order to prevent trouble caused by moisture in the compressed air supplied thereto. Is being used. In this refrigeration air dryer, in order to prevent condensation of the air pipe on the secondary side of the air dryer by the low temperature compressed air dehumidified by cooling, the compressed air at the outlet of the air dryer to increase the temperature again. It is required to control the temperature of the.

3 shows a circuit of a refrigerant system and an air system of a system capable of controlling the temperature of compressed air at the outlet of the air dryer in a conventional refrigeration air dryer. The refrigerant system in the refrigeration air dryer includes a refrigerant compressor (10), a condenser (11) compressed by the refrigerant compressor (10), and condensed with a high temperature refrigerant transferred through the high temperature refrigerant pipe (22); And expansion valve 12 for reducing the refrigerant condensed by the condenser 11 by adiabatic expansion to obtain a low temperature, and wet compressed air introduced from the air inlet 20 of the air system. It has a cooler 13 which cools and dehumidifies with the low temperature refrigerant | coolant from the refrigerant | coolant, and the refrigerant from this cooler 13 is comprised so that it may return to the said refrigerant | coolant compressor 10 via the return refrigerant piping 26. As shown in FIG.

Meanwhile, the air system cools the wet compressed air (primary air) introduced from the outside through the air inlet 20 by the cooler 13, and then drains off by the drain separator 16 to dehumidify the low temperature. The dehumidifying air is used as air and is reheated by the electric heater 14 to be transferred to the outlet pipe 21 as secondary air. In the temperature control of the secondary air at the outlet of the air dryer, a temperature sensor 40 is provided in the outlet pipe 21, and the temperature of the secondary air detected by the temperature sensor 40 is controlled by the temperature controller 41. ), And by controlling the output of the electric heater 14 by the temperature controller 41, temperature control can be performed with high accuracy. Moreover, the drain separator 16 which performs the said drain separation is provided with the drain valve 15 which isolate | separates the generated water droplet and discharges it to the exterior.

In this conventional refrigeration air dryer, since the low temperature dehumidification air dehumidified by cooling is reheated by the electric heater 14, the electric power of about the same as a refrigerator is required. For this reason, the conventional refrigeration air dryer has a disadvantage in that power consumption increases even though temperature control can be performed with high accuracy.

On the contrary, in place of the electric heater 14, a heater for heat exchanging the warm primary air flowing from the air inlet 20 and the low temperature dehumidifying air passing through the cooler 13 by their temperature difference is provided. In addition to preliminary cooling of the primary air by heat exchange, a technique of raising the temperature of the dehumidifying air and outputting it as secondary air is also known. In the case where such a Richter is installed, the primary air is precooled and then recooled by the cooler, thereby reducing the load on the refrigerating circuit. In addition, condensation of the air piping can be prevented by raising the temperature of the secondary air sent from the air dryer. For this reason, thermal energy can be utilized effectively. However, when the temperature of the secondary air depends on the temperature of the primary air and the temperature of the primary air from the air inlet 20 is low, the temperature of the secondary air from the outlet pipe 21 is converted into the outlet pipe. It may not be possible to raise the temperature to a temperature at which condensation of (21) can be prevented, and it is difficult to stably control the temperature in a predetermined temperature range.

Incidentally, in the above conventional refrigeration air dryer, the temperature of the high temperature refrigerant flowing from the refrigerant compressor 10 through the high temperature refrigerant pipe 22 to the condenser 11 is about 90 ° C. The temperature of the low temperature refrigerant flowing through the low temperature refrigerant pipe 23 and passing through the low temperature refrigerant pipe 23 through the low temperature refrigerant pipe 23 is about 5 ° C. In addition, the temperature of the primary air flowing from the air inlet 20 is 40 ° C (rated), and the temperature of the dehumidified air transferred from the cooler 13 to the electric heater 14 via the drain separator 16 is about 10. ℃.

In the refrigeration air dryer, a high temperature refrigerant pipe 22 connecting the refrigerant compressor 10 and a condenser 11 and a low temperature refrigerant pipe 23 connecting the expansion valve 12 and the cooler 13 are provided. It is connected by the bypass refrigerant pipe 25 provided with the capacity | capacitance adjustment valve 17 which can adjust an opening degree. As described below, the bypass refrigerant pipe 25 is a refrigerant so that the temperature of the refrigerant flowing in the cooler 13 is excessively lowered so that moisture in the primary air flowing from the air inlet 20 to the cooler 13 is not frozen. This is for mixing a part of the refrigerant flowing from the compressor 10 to the condenser 11.

The technical problem of the present invention is that unlike the conventional refrigeration air dryer, there is no need to heat the secondary air in the outlet pipe by using an electric heater, and uses heat generated in the refrigerant system to raise the temperature of the secondary compressed air. A refrigeration air dryer is provided in which a temperature of the secondary air in the outlet pipe can be precisely controlled in the same manner as in the case of using an electric heater by adjusting the flow rate of the refrigerant or air flowing through the Richter using the Richter.

In order to solve the above problems, according to the present invention, there is provided a refrigerant compressor, a condenser for condensing a high temperature refrigerant compressed by the refrigerant compressor, a decompression mechanism for reducing the refrigerant condensed by the condenser by adiabatic expansion to a low temperature; And a cooler configured to cool and dehumidify the wet compressed air introduced from the air inlet of the air system by the low temperature refrigerant from the depressurization mechanism, and the coolant system configured to return the refrigerant from the cooler to the refrigerant compressor; And the air inlet through which the wet compressed air to be dehumidified is introduced as the primary air, the cooler which cools the primary air introduced from the air inlet to form low temperature dehumidification air, low temperature dehumidification air and the refrigerant from the cooler. An air system having a richer for exchanging heat of a high temperature refrigerant from a refrigerant compressor of the system, and outputting dehumidified air heated by heat exchange in the richer as secondary air from an outlet pipe; Provided is a refrigerated air dryer. On the basis of the temperature sensor for detecting the temperature of the secondary air flowing through the outlet pipe, the valve means for adjusting the flow rate of the dehumidifying air or the refrigerant flowing through the Richter, and the detection temperature of the temperature sensor. By controlling the valve means has a temperature controller for controlling the flow rate of the dehumidified air or the refrigerant to maintain a constant temperature of the secondary air.

In the air dryer of the present invention, it is preferable that the Richter is connected between the refrigerant compressor and the condenser, and the refrigerant from the refrigerant compressor is configured to be transferred to the condenser via the Richter.

In addition, a capacity regulating valve capable of adjusting an opening degree of a high temperature refrigerant pipe connecting the refrigerant compressor and the Richter, a low temperature refrigerant pipe connecting the decompression mechanism and the cooler, or a return refrigerant pipe connecting the cooler and the refrigerant compressor. When the load of the cooler is reduced by communicating with the bypass refrigerant pipe having, a portion of the high temperature refrigerant compressed by the refrigerant compressor may be configured to flow directly into the low temperature refrigerant pipe or the return refrigerant pipe.

In the present invention, the valve means preferably consists of a three-way flow regulating valve having one inlet port and two outlet ports, and the three-way flow regulating valve is used to supply a part of the dehumidifying air or the refrigerant directed toward the Richter. It is configured to circumvent the flow.

In this case, a dehumidification air pipe for transferring the dehumidifying air from the cooler to the Richter and a bypass pipe for bypassing the Richter are connected to an outlet pipe for outputting secondary air from the Richter, and the bypass pipe and the dehumidifying air are connected. The three-way flow regulating valve may be provided at a branch portion where the pipe is branched or at a confluence portion at which the bypass pipe and the outlet pipe join.

Alternatively, a high temperature refrigerant pipe connecting the refrigerant compressor and the Richter and a refrigerant bypass pipe bypassing the Richter are connected to a relay refrigerant pipe connecting the Richter and the condenser, and the refrigerant bypass pipe and the high temperature refrigerant pipe are branched. The three-way flow rate adjustment valve may be provided at a confluence of the base or the refrigerant bypass pipe and the relay refrigerant pipe.

In the refrigerated air dryer of the present invention having the above-described configuration, the temperature is increased based on the temperature of the dehumidified air that is drained into the Richter or the flow rate of the refrigerant from the refrigerant compressor based on the temperature of the dehumidified air flowing through the outlet pipe. Since it is controlled to be constant, the flow rate can be controlled relatively accurately easily by an electric means, and thus the temperature of the compressed air of the outlet pipe can be precisely controlled similarly to the case of using an electric heater while using a Richter.

According to the refrigeration air dryer of the present invention described above, the refrigerant system does not heat the dehumidification air temperature of the outlet pipe by using an electric heater as in the conventional refrigeration air dryer, but occurs in the refrigerant system at the elevated temperature of the compressed air of the outlet pipe. The temperature of the compressed air in the outlet pipe can be precisely controlled in the same manner as in the case of using the electric heater by adjusting the flow rate of the fluid flowing through the Richter while using the Richter using the heat.

1 shows a first embodiment of a refrigerated air dryer according to the present invention, and FIG. 2 shows a second embodiment of a refrigerated air dryer according to the present invention. In these Examples, the same code | symbol as the code | symbol attached to FIG. 3 is attached | subjected to the element common to the conventional refrigeration air dryer shown in FIG.

The refrigeration air dryer according to the first embodiment of FIG. 1 is divided into large parts and refrigerated by controlling the flow rate of the dehumidifying air or the refrigerant flowing through the refrigerant system, the air system, and the Richter 18 connected to the refrigerant system and the air system. It is provided with the control system which keeps the temperature of secondary air output from a type | mold air dryer constant.

The refrigerant system includes a refrigerant compressor (10), a high temperature refrigerant pipe (22) for transferring the refrigerant compressed by the refrigerant compressor (10) to a temperature of the Richter (18), and a relay refrigerant from the Richter (18). A condenser 11 for condensing the refrigerant conveyed through the pipe 27, an expansion valve 12 for reducing the refrigerant condensed by the condenser 11 by adiabatic expansion to a low temperature, and the air of the air system It has a cooler 13 which cools and dehumidifies the humid compressed air which flowed in from the inlet 20 by the low temperature refrigerant | coolant from the expansion valve 12, and the refrigerant from the cooler 13 returns the return refrigerant piping 26 It is configured to return to the refrigerant compressor 10 through.

In addition, the said expansion valve 12 is shown as an example of the said pressure reduction mechanism, For example, a capillary tube etc. can also be used instead of the said expansion valve.

On the other hand, the air system of this refrigeration air dryer is the air inlet 20, which is introduced from the outside as warm and humid compressed air (rated temperature 40 ℃) dehumidification target as the primary air, and the air inlet 20 By the cooler 13 which cools primary air and condenses moisture, the drain separator 16 which dehumidifies the compressed air cooled by the cooler 13 by drain separation, and the drain separator 16, It has the said Richter 18 which heat-exchanges the low temperature dehumidified air which drained off with the high temperature refrigerant | coolant compressed by the refrigerant | coolant compressor 10 in the said refrigerant system, By the heat exchange in the Richter 18 It is comprised so that the said dehumidification air of high temperature may be heated up, and the dehumidification air heated up may be conveyed to the said outlet piping 21 as secondary air.

Thus, the cooler 13 and the richer 18 are connected to both the refrigerant system and the air system to functionally combine these refrigerant systems and the air system.

Further, the drain separator 16 for separating the drain is provided with a drain valve 15 for separating the generated water droplets and discharging them to the outside.

The control system for maintaining a constant temperature of the secondary air flowing through the outlet pipe 21 is a three-way flow rate control valve 30 connected in the dehumidification air pipe 28 connecting the drain separator 16 and the Richter 18. Has The three-way flow regulating valve 30 has one inlet port 30a and two outlet ports 30b and 30c, and the dehumidified air introduced from the inlet port 30a receives two outlet ports 30b and 30c. It outputs in the state which distribute | arranged from the flow volume, The upstream side part 28a which connects to the said drain separator 16 of the said dehumidification air piping 28 is connected to the said inlet port 30a, and one outlet port 30b is connected. The downstream side portion 28b of the dehumidifying air pipe 28 that leads to the richer 18 is connected to the bypass port 29, which is connected to the output port 30c on the branch side and the outlet pipe 21. have.

The bypass pipe 29 is a part of the dehumidified air in the dehumidified air pipe 28 bypasses the Richter 18 and flows directly to the outlet side of the Richter 18. The bypass pipe 29 allows the Richter to flow. The flow rate of the dehumidifying air flowing in 18 is adjusted.

In addition, the control system has a temperature sensor 40 connected to the outlet pipe 21 to detect the temperature of the secondary air flowing in the outlet pipe 21, and the temperature sensor 40 and the three-way flow regulating valve. 30 is connected to the temperature controller 42. Dehumidified air passing through the Richter 18 by controlling the three-way flow regulating valve 30 by the temperature controller 42 based on the detected temperature of the secondary air detected by the temperature sensor 40; The flow rate of the dehumidifying air bypassing the Richter 18 is controlled.

The temperature controller 42 compares the set temperature target value with the actual detected temperature detected by the temperature sensor 40 so that their difference becomes zero, that is, the secondary air in the outlet pipe 21 By controlling the opening degree of the three-way flow control valve 30 so that the temperature is constant, the flow rate of the dehumidifying air flowing in the bypass pipe 29 and the richter 18 is controlled.

In addition, the three-way flow regulating valve 30 does not have to be a sole valve, and controls the flow rate of the dehumidifying air flowing through the bypass pipe 31 and the richer 18 based on the signal from the temperature controller 42. As long as it can, the combination of some valve may be sufficient.

In the refrigeration air dryer of the first embodiment having such a configuration, the temperature of the secondary air flowing through the outlet pipe 21 is detected by the temperature sensor 40, and the bypass pipe 29 is based on the detected temperature. And the flow rate of the dehumidifying air flowing through the Richter 18, the temperature of the secondary air output from the outlet pipe 21 is precisely controlled as in the case of using the Richter 18, but using a conventional electric heater can do.

Next, the refrigeration air dryer which concerns on 2nd Example of this invention shown in FIG. 2 is demonstrated, comparing with 1st Example. In the refrigerant system of the second embodiment, a three-way flow regulating valve 32 controlled by the temperature controller 42 is provided in the high temperature refrigerant pipe 22 connecting the refrigerant compressor 10 and the Richter 18. This three-way flow regulating valve 32 is the same as the three-way flow regulating valve 30 in the first embodiment, and has one inlet port 32a and two outlet ports 32b and 32c. An upstream portion 22a leading to the refrigerant compressor 10 of the high temperature refrigerant pipe 22 is connected to a port 32a, and one of the outlet ports 32b of the Richter of the high temperature refrigerant pipe 22 A downstream portion 22b leading to 18 is connected, and one end of the refrigerant bypass pipe 31 is connected to the other output port 32c on the branch side, and the other end of the refrigerant bypass pipe 31 is connected to the Richter. It is connected to the relay refrigerant pipe 27 which connects the outlet of 18 to the condenser 11. The refrigerant bypass pipe 31 bypasses the Richter 18 by a part of the refrigerant in the high temperature refrigerant pipe 22 and flows directly to the outlet side of the Richter 18.

Since the configuration of this refrigeration air dryer of this second embodiment is not substantially different from that of the refrigeration air dryer of the first embodiment, the description of the common parts thereof is omitted here.

The three-way flow regulating valve 32 is provided to the temperature controller 42 so that the temperature of the secondary air in the outlet pipe 21 detected by the temperature sensor 40 becomes equal to the target value set in the temperature controller 42. Is controlled by The control is substantially the same as the control of the three-way flow regulating valve 30 in the first embodiment.

In addition, the three-way flow regulating valve 32 in the second embodiment does not need to be a single valve as in the three-way flow regulating valve 30 in the first embodiment. A plurality of valves may be combined as long as the flow rate of the dehumidifying air flowing through the bypass pipe 31 and the richer 18 can be controlled based on the signal.

On the other hand, unlike the air system in the refrigeration air dryer of the first embodiment, the air system in the second embodiment uses low-temperature dehumidified air drain-separated by the drain separator 16 to the Richter 18. The whole amount flows through the dehumidification air piping 28. However, other configurations except this point are not substantially different from the refrigerated air dryer of the first embodiment.

In the second embodiment, as described above, the three-way flow rate regulating valve 32 is provided in the high temperature refrigerant pipe 22 connecting the refrigerant compressor 10 and the Richter 18 and the high temperature flowing through the Richter 18. By controlling the flow rate of the coolant, the temperature of the secondary air in the outlet pipe 21 detected by the temperature sensor 40 can be controlled to be the target value set in the temperature controller 42 as in the case of the first embodiment. Can be. In addition, in FIG. 2 which shows 2nd Example, the code | symbol same as 1st Example is attached | subjected to the element common to 1st Example.

In the first embodiment, the bypass pipe 29 is branched from the dehumidifying air pipe 28 through which the dehumidifying air flows into the Richter 18, so that the three-way flow rate adjustment valve is formed at the branch of both pipes 28 and 29. Although 30) is provided, the three-way flow regulating valve 30 may be provided at a confluence where the bypass pipe 29 and the outlet pipe 21 join, instead of being provided at the branch.

In the second embodiment, the refrigerant bypass pipe 31 is branched from the high temperature refrigerant pipe 22 which transfers the refrigerant from the refrigerant compressor 10 to the Richter 18, and the three-way flow regulating valve ( Although 32 is provided, the three-way flow regulating valve 32 is joined to the junction of the refrigerant bypass pipe 31 and the relay refrigerant pipe 27 on the outlet side of the Richter 18 instead of being installed at the branch. Can also be installed on

When the three-way flow rate adjustment valve is provided at the confluence of the pipes in this way, the flow rate of the dehumidifying air or the refrigerant flowing through the Richter 18 and the bypass pipe 29 or 31 based on the control signal from the temperature controller 42. Of course it is controlled.

In addition, the three-way flow regulating valve provided at the confluence portion does not have to be a single valve, but dehumidified air flows through the Richter 18 and the bypass pipe 29 or 31 based on a signal from the temperature controller 42. Alternatively, as long as the flow rate of the refrigerant can be controlled, a plurality of valves may be combined.

Further, in the first and second embodiments, the high temperature refrigerant pipe 22 connecting the refrigerant compressor 10 and the Richter 18 and the low temperature refrigerant pipe connecting the expansion valve 12 and the cooler 13 ( 23 is connected by the bypass refrigerant pipe 25 provided with the capacity | capacitance adjustment valve 17 which can adjust an opening degree. When the load of the cooler 13 is reduced, the bypass refrigerant pipe 25 is caused by excessively lowering the temperature of the refrigerant flowing from the expansion valve 12 to the cooler 13 through the low temperature refrigerant pipe 23. The capacity adjusting valve 17 is opened by a necessary amount so that moisture in the wet primary air flowing from the inlet 20 to the cooler 13 is not frozen, and a part of the high temperature refrigerant from the refrigerant compressor 10 is released from the heater 18. ), The condenser 11 and the expansion valve 12 are bypassed to be mixed with the low temperature refrigerant in the low temperature refrigerant pipe 23 to maintain the temperature of the low temperature refrigerant so as not to fall below a predetermined temperature. Therefore, the bypass refrigerant pipe 25 serves to adjust the flow rate of the refrigerant flowing through the Richter 18, the condenser 11, and the expansion valve 12.

The bypass refrigerant pipe 25 may be connected to the high temperature refrigerant pipe 22 and the return refrigerant pipe 26 connecting the cooler 13 and the refrigerant compressor 10. In this case, the flow rate of the refrigerant flowing in the cooler 13 is reduced, thereby obtaining the same effect as that described above, i.e., preventing freezing of water in the air cooled by the cooler 13.

The temperature of the refrigerant and compressed air in each of the refrigerant system and the air system in the refrigeration air dryers of the first and second embodiments except the temperature of the secondary air in the outlet pipe 21, Although not much different from the case of the conventional refrigeration air dryer of FIG. 3, the temperature of the secondary air in the outlet pipe 21 is controlled in each embodiment, so that the temperature can be stabilized. In addition, since the flow rate of the dehumidified dehumidified air or the refrigerant from the refrigerant compressor 10 drained into the Richter 18 is controlled to be constant based on the temperature of the secondary air flowing through the outlet pipe 21. The flow rate can be controlled relatively accurately by electrical means, and thus the temperature of the secondary air in the outlet pipe 21 can be precisely controlled similarly to the case where the electric heater is used while the Richter 18 is used. .

1 is a circuit diagram of a refrigeration system and an air system of a first embodiment of a refrigerated air dryer according to the present invention.

2 is the same circuit diagram as the second embodiment of the refrigerated air dryer according to the present invention.

3 is a circuit diagram of a refrigeration system and an air system of a conventional refrigeration air dryer.

Claims (6)

A refrigerant compressor, a condenser for condensing the high temperature refrigerant compressed by the refrigerant compressor, a decompression mechanism for reducing the refrigerant condensed by the condenser by adiabatic expansion to a low temperature, and a humid inlet from the air inlet of the air system. A coolant system having a cooler for cooling compressed air by a low temperature refrigerant from the depressurization mechanism and dehumidifying, the refrigerant from the cooler being configured to return to the refrigerant compressor; And a cooler for cooling the primary air introduced from the air inlet, wherein the humid compressed air, which is a dehumidification target, is introduced as primary air, to cool the dehumidified air into a low temperature dehumidifying air, low temperature dehumidified air from the cooler, and the refrigerant. In a refrigeration air dryer having a Richter for heat-exchanging the high-temperature refrigerant from the refrigerant compressor of the system, and having an air system for outputting the dehumidified air heated by the heat exchange in the Richter as secondary air from the outlet pipe. : The air dryer includes a temperature sensor for detecting the temperature of the secondary air flowing through the outlet pipe, a valve means for adjusting the flow rate of the dehumidifying air or the refrigerant flowing through the Richter, and the valve means based on the detected temperature of the temperature sensor. And a temperature controller for controlling the flow rate of the dehumidified air or the refrigerant to maintain a constant temperature of the secondary air. The refrigeration air dryer according to claim 1, wherein the Richter is connected between the refrigerant compressor and the condenser, and the refrigerant from the refrigerant compressor is configured to be transferred to the condenser via the Richter. 3. The method of claim 2, wherein the opening degree of the high temperature refrigerant pipe connecting the refrigerant compressor and the Richter and the low temperature refrigerant pipe connecting the decompression mechanism and the cooler or the return refrigerant pipe connecting the cooler and the refrigerant compressor can be adjusted. When the load of the cooler is reduced by communicating by a bypass refrigerant pipe having a capacity regulating valve, a portion of the high temperature refrigerant compressed by the refrigerant compressor flows directly into the low temperature refrigerant pipe or the return refrigerant pipe. Refrigerated air dryer characterized in that. 4. The dehumidifying air according to any one of claims 1 to 3, wherein the valve means consists of a three-way flow regulating valve having one inlet port and two outlet ports, and dehumidified air directed to the Richter by the three-way flow regulating valve. Or a portion of the refrigerant to flow by bypassing the Richter. The dehumidification air pipe which transfers the dehumidification air from the said cooler to the said Richter, and the bypass pipe which bypasses the said Richter to the outlet pipe which outputs the secondary air from the said Richter, The said bypass piping And the three-way flow rate adjustment valve is provided at a branch portion at which the dehumidifying air pipe is branched or at a joining portion at which the bypass pipe and the outlet pipe are joined. 5. The refrigerant bypass pipe according to claim 4, wherein a high temperature refrigerant pipe connecting the refrigerant compressor and the Richter and a refrigerant bypass pipe bypassing the Richter are connected to a relay refrigerant pipe connecting the Richter and the condenser. And the three-way flow regulating valve is provided at a branch portion at which the high temperature refrigerant pipe is branched or at a junction portion at which the refrigerant bypass pipe and the relay refrigerant pipe are joined.

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