JP5497357B2 - Compressed air supply device for vehicles - Google Patents

Description

  The present invention relates to a vehicle compressed air supply device that supplies compressed air to a vehicle brake, for example.

  Conventionally, in a large vehicle such as a truck or a bus, an air-type brake device using compressed air as a working fluid for operating the brake chamber has been adopted. In this type of brake device, a vehicle that supplies compressed air to each brake chamber. Compressed air supply device is installed. The vehicle compressed air supply device includes an air compressor, stores compressed air discharged from the air compressor in an air tank, and supplies the compressed air in the air tank to each brake chamber as necessary. An air dryer having an adsorbent (drying agent) that adsorbs moisture of compressed air is provided between the air compressor and the air tank (see, for example, Patent Document 1). The apparatus disclosed in Patent Document 1 regenerates the adsorbent during the unloading of the air compressor, thereby continuously removing moisture from the compressed air.

Japanese National Patent Publication No. 5-505758

By the way, in the conventional compressed air supply device, if the deterioration of the adsorbent progresses with continued use, the adsorbent becomes difficult to recover even if it is regenerated as described above. Is common. Adsorbent replacement timing has been determined by using a method that uses the distance traveled by the vehicle as a guide or a method that estimates the state of the adsorbent based on the pressure and air flow rate in the air dryer. Since this is a method for estimating the state, the adsorbent replacement time may be made earlier than necessary.
In order to solve this problem, a humidity sensor is installed downstream of the desiccant, and the deterioration of the adsorbent is determined by the detection value (humidity value) of the humidity sensor after the desiccant is regenerated. A configuration that accurately determines the time is assumed. However, it has been found that the detection value of the humidity detection sensor differs depending on the environment (air flow rate and ambient temperature) at the position where the sensor is attached. Further, the mounting position of the sensor often differs depending on the vehicle, and it is assumed that it is difficult to accurately determine the desiccant replacement time based on the detection value of the sensor.
Accordingly, an object of the present invention is to make it possible to accurately determine the replacement timing of a desiccant for removing moisture from compressed air discharged from an air compressor regardless of the mounting position of a humidity detection sensor. .

In order to achieve the above object, the present invention includes an air compressor mounted on a vehicle, and a compressed air supply device for a vehicle that supplies compressed air discharged from the air compressor to a load of the vehicle. An air dryer that is provided in the discharge line to remove foreign substances such as moisture contained in the compressed air, a humidity detection sensor that is attached downstream of the desiccant of the air dryer, and a desiccant of the air dryer at a predetermined timing Regenerating means for regenerating, and the detection value of the humidity detection sensor after the desiccant is regenerated by the regenerating means is set corresponding to the flow rate of compressed air at the mounting position of the humidity detection sensor Deterioration determination means for determining the replacement timing of the desiccant by determining whether or not the desiccant adsorption capacity is not recovered by the regeneration compared to a threshold value The provided, and outside air temperature detection sensor for detecting the outside air temperature, detected and correcting means for correcting the threshold value according to the outside air temperature, temporarily storable air tank air foreign matter has been removed by the air dryer And a brake device as the load to which the air in the air tank is supplied, the humidity detection sensor, a supply path connecting the air dryer and the air tank, a tank central portion of the air tank, The humidity detection sensor can be attached to any one of a tank inner wall surface of the air tank, a brake valve of the brake device, and a connecting pipe connecting the brake chamber of the brake device and the brake valve. Is attached, the threshold value for determining the deterioration of the desiccant from the detected humidity value, The supply passage connecting the air dryer and the air tank is larger than the threshold when the humidity sensor is attached to the center of the air tank, the brake valve of the brake device, the brake chamber of the brake device and the brake The humidity sensor is set to be smaller than a threshold value when the humidity sensor is attached to any one of the connecting pipes connected to the valve, and the deterioration determination unit is configured to detect the humidity sensor after the desiccant is regenerated by the regeneration unit. The detected value is compared with each threshold value set corresponding to the flow rate of compressed air at the mounting position of the humidity detection sensor, and the desiccant is deteriorated to determine the replacement time of the desiccant, and the correcting means Is characterized in that the correction amount is adjusted according to the flow velocity of the compressed air .

  In this configuration, the threshold value may be set to be large when the humidity detection sensor is attached to a position where the flow velocity of the compressed air is fast, and small when the humidity detection sensor is attached to a location where the flow velocity of the compressed air is slow. good.

  According to the present invention, the detection value of the humidity detection sensor after the desiccant is regenerated is compared with a threshold value corresponding to the flow rate of the compressed air at the mounting position of the humidity detection sensor. In order to determine the deterioration, regardless of the mounting position of the humidity detection sensor, it is possible to accurately determine the deterioration of the adsorption performance of the desiccant that removes moisture and the like, and the desiccant can be replaced at an appropriate time.

It is a figure which shows the structure of the compressed air supply system which concerns on embodiment of this invention. It is sectional drawing which shows the structure of an air dryer. It is a schematic diagram which shows the position where a humidity detection sensor is attached. It is a relationship figure which shows the relationship between the attachment position of a humidity detection sensor, and a threshold value. It is a flowchart which shows operation | movement of an air dryer module.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing a configuration of a compressed air supply system 1 according to an embodiment to which the present invention is applied.
A compressed air supply system 1 (vehicle compressed air supply apparatus) shown in FIG. 1 is an apparatus that supplies compressed air for driving to an air brake device or the like mounted on a large vehicle such as a truck or a bus. Compressor 4 (air compressor), ECU 2 that controls the compressor 4, and air that removes moisture from the compressed air discharged from the compressor 4 and supplies dry compressed air to the vehicle load (for example, brake device) The dryer module 10 is provided.
The ECU 2 controls the engine of the vehicle and the operations of the compressor 4 and the air dryer module 10 based on the vehicle speed of the vehicle on which the compressed air supply system 1 is mounted. Further, a temperature sensor (outside air temperature detection sensor) 5 is connected to the ECU 2 and information indicating the temperature detected by the temperature sensor 5 is input. The temperature sensor 5 is a temperature sensor disposed at a portion that comes into contact with the outside air of the vehicle, for example, between a mechanism portion outside the vehicle body. Specifically, the temperature sensor 5 is composed of a thermistor or a thermocouple, The corresponding voltage value is output. Further, the ECU 2 is input with information related to the vehicle running speed such as information related to the vehicle speed of the vehicle, information related to the travel distance of the vehicle, and information related to the operating status of the air dryer 11.

The air dryer module 10 is connected to loads 51 to 54 included in the vehicle, and each of the loads 51 to 54 includes a compressed air circuit through which compressed air flows. The loads 51 to 53 constitute the brake device described above. In this embodiment, the load 51 is a main brake (front wheel), the load 52 is a main brake (rear wheel), and the load 53 is a parking brake. The load 54 is an accessory driven by compressed air such as a horn or a clutch drive mechanism. The loads 51 and 52 (main brake) require a larger amount of air during operation than the other loads 53 and 54 (parking brakes and accessories). For this reason, air tanks 51a and 52a capable of temporarily storing compressed air dried by the air dryer module 10 are provided between the air dryer module 10 and the loads 51 and 52, respectively. , 52a is supplied to the loads 51, 52.
The air dryer module 10 detects the air pressure in each part of the solenoid valves 101, 102, and 103 and the air dryer module 10 that are opened and closed under the control of the ECU 2, and outputs pressure values 121, 122, and 123 to the ECU 2. , 124 are provided. The ECU 2 opens and closes the electromagnetic valves 101 to 103 based on the detection values of the pressure sensors 121 to 123.

  The compressor 4 is connected to the engine via an auxiliary belt (not shown), and compresses air by the driving force of the engine. The compressor 4 is controlled by air pressure, and a solenoid valve 101 is connected to this control line. Switching between a load state in which the compressor 4 compresses air and an unload state in which compression is not performed is performed by opening and closing the solenoid valve 101. It is done.

The discharge pipe 41 of the compressor 4 is connected to the inflow pipe 111 of the air dryer module 10, and the air dryer 11 is connected to the inflow pipe 111. The air dryer 11 contains a desiccant 231 in the case 20, and removes foreign matters such as moisture contained in the compressed air discharged from the compressor 4 by the desiccant 231.
An exhaust valve 12 is provided between the compressor 4 and the air dryer 11. When the exhaust valve 12 is opened, the compressed air in the main body of the air dryer 11 is discharged directly from the exhaust port 112 to the outside. The exhaust valve 12 is controlled by air pressure, and a double check valve 104 is connected to the control line. The exhaust valve 12 is normally closed and is opened only when air pressure is applied from the double check valve 104.

The air dryer module 10 includes a governor 13 that is mechanically operated by air pressure to control opening and closing of the exhaust valve 12. The governor 13 operates according to the air pressure in the supply passage 106 on the downstream side of the air dryer 11 and opens when the air pressure exceeds a predetermined value to apply air pressure to the double check valve 104.
On the other hand, the electromagnetic valve 102 is opened and closed under the control of the ECU 2, and applies the air pressure of the supply passage 106 to the double check valve 104 in the valve open state.
The double check valve 104 opens the exhaust valve 12 by applying air pressure when either the governor 13 or the electromagnetic valve 102 is opened. Therefore, the exhaust valve 12 is opened when the air pressure in the supply path 106 is higher than a predetermined value and when the electromagnetic valve 102 is opened, and the compressed air is discharged from the exhaust port 112.

  Here, when the exhaust valve 12 is opened while the air pressure in the air dryer module 10 is sufficiently high, the air is stored in the downstream side of the air dryer 11 (for example, in the supply passage 106 and the air tanks 51a and 52a). The compressed air flows back through the case 20 of the air dryer 11 and is discharged from the exhaust port 112. At this time, air passing through the case 20 becomes super dry due to rapid pressure reduction, and moisture is taken away from the desiccant 231 in the case 20, so that the desiccant 231 is regenerated. The regenerated desiccant 231 has recovered the adsorptive capacity to adsorb moisture, and can remove moisture from the compressed air. This regeneration operation is performed by a predetermined regeneration timing such as when the electromagnetic valve 102 is opened by the ECU 2 so that the air pressure in the air dryer module 10 satisfies a preset condition at every preset time. It is executed at (predetermined timing). In this embodiment, the ECU 2 and the electromagnetic valve 102 function as a regeneration unit that regenerates the desiccant 231 of the air dryer 11.

  The air dryer module 10 includes an output port 113 to which a load 51 (front brake main brake) is connected, an output port 114 to which a load 52 (rear wheel main brake) is connected, and an output to which a load 53 (parking brake) is connected. A port 115 and an output port 116 to which a load 54 (accessories) is connected are provided. An air tank 51a is connected to the output port 113, and an air tank 52a is connected to the output port 114.

  A branch chamber 135 is connected to the supply path 106 downstream from the air dryer 11 via a pressure reducing valve 131. The branch chamber 135 is connected to a supply path connected to the output port 113 and a supply path connected to the output port 114. The supply path connected to the output port 113 is provided with a protective valve 141, and the supply path connected to the output port 114 is connected to the supply path connected to the output port 114. A protection valve 142 is provided. A pressure reducing valve 132 is connected to the branch chamber 135, and the downstream of the pressure reducing valve 132 branches into a supply path connected to the output port 115 and a supply path connected to the output port 116, and protective valves 143 and 144 are provided, respectively. ing. Each of the protection valves 141 to 144 is arranged in parallel with the throttle and the check valve, and closes when a circuit through which compressed air flows is lost in the loads 51 to 54 connected to the corresponding output ports 113 to 116, respectively.

In addition, a pressure reducing valve 133 is disposed on the downstream side of the protective valve 144 in the supply path that connects the pressure reducing valve 132 to the output port 116, and the compressed air that has been decompressed is supplied to the load 54.
Furthermore, a supply path 136 that bypasses the protection valve 143 and is connected to the output port 115 extends in the supply path between the pressure reducing valve 132 and the protection valve 143. The supply path 136 includes a check valve 137 that prevents the backflow of compressed air from the output port 115 to the branch chamber 135, and a throttle 138 that is arranged in series with the check valve 137.

  The pressure sensor 121 detects the air pressure in the supply path 106, the pressure sensor 122 detects the air pressure downstream of the protection valve 141, that is, the output port 113, the pressure sensor 123 detects the air pressure in the output port 114, and the pressure sensor 124. Detects the air pressure at the output port 115. These detected values are output from the pressure sensors 121 to 124 to the ECU 2 as needed.

  The vehicle parking brake device corresponding to the load 53 is enabled to travel with the braking force released by the air pressure. Specifically, the parking brake is configured to exert a braking force by expanding the brake shoe with the spring force during parking, and closes the brake shoe against the spring force by the air pressure supplied from the air dryer module 10 when released. It has become. Although the load 53 of the present embodiment does not include an air tank that stores compressed air, the air dryer module 10 shown in FIG. 1 can reliably operate the load 53 without an air tank.

  That is, the protection valves 141 and 142 are in the open state when the compressed air is sufficiently filled in the compressed air circuits of the corresponding loads 51 and 52, respectively. Accordingly, the compressed air in the main brake air tanks 51 a and 52 a can be supplied from the branch chamber 135 through the pressure reducing valve 132 to the output port 115 through the supply path 136. For this reason, when the air pressure in the air tanks 51a and 52a is sufficiently high, the parking brake can be released by supplying compressed air to the load 53.

  On the other hand, when the air pressure in the air tanks 51 a and 52 a is not sufficient, the ECU 2 opens the solenoid valve 103, the command pressure of the solenoid valve 103 is given to the check valve 137, and the supply path 136 is closed by the check valve 137. The compressed air supply path to the output port 115 is blocked. In this case, the parking brake cannot be released, but it is preferable not to release the parking brake when the air tanks 51a and 52a used for the main brake have insufficient air pressure. Further, the parking brake can be released when the air pressure in the air tanks 51a and 52a is restored. Therefore, even if there is no air tank for the load 53, the parking brake can be stably operated by the compressed air.

FIG. 2 is a cross-sectional view illustrating a specific configuration example of the air dryer 11.
As shown in FIG. 2, the case 20 of the air dryer 11 includes a dryer body 21 and a cartridge cover 22 that covers the dryer body 21 and is fixed by bolts 221. The dryer main body 21 is connected to an inflow pipe 111 (FIG. 1), an inlet 211 into which compressed air discharged from the discharge pipe 41 of the compressor 4 flows, and a supply path 106 (see FIG. And an outlet 212 connected to 1).

A cartridge 23 is accommodated in a hollow cartridge cover 22 fixed to the upper part of the dryer body 21. The cartridge 23 is fixed to the dryer main body 21 by bolts 235 so that compressed air does not leak out of the cartridge 23.
A space is formed inside the cartridge 23, and this space is filled with a granular desiccant 231. A check valve 232 that discharges compressed air to the outside of the cartridge 23 is provided at the upper end of the cartridge 23. A filter 234 and a spring 233 that press the desiccant 231 from the check valve 232 side are provided below the check valve 232. It is arranged.
In addition, an oil filter 24 that collects oil mist in the circulating air is disposed below the cartridge 23 in order to prevent oil from entering the space in which the desiccant 231 is stored.

The compressed air that has flowed in from the inlet 211 of the desiccant 231 enters the inflow side air chamber 213 provided in the dryer main body 21, and further passes through a flow path (not shown) formed in the dryer main body 21 to the cartridge 23. Inflow. Here, the flow path in the dryer body 21 is connected to the oil filter 24, and the compressed air that has passed through the oil filter 24 reaches the desiccant 231.
The compressed air from which oil has been removed by the oil filter 24 and from which moisture has been adsorbed and removed by the desiccant 231 of the cartridge 23 passes out of the cartridge 23 through the check valve 232 and is provided in the cartridge cover 22. It passes through a flow path (not shown) and flows out of the dryer main body 21 from the outlet 212.

In the dryer main body 21, an exhaust valve 12 is provided in a flow path through which compressed air flows from the inlet 211 to the cartridge 23. The exhaust valve 12 is a valve for discharging the compressed air in the case 20 to the outside as described above. An exhaust pipe 215 is connected to the lower part of the exhaust valve 12, and a silencer 217 is accommodated in the exhaust pipe 215. In addition, a collar 216 is connected to the lower end of the exhaust pipe 215, and a silencer 218 is also housed inside the collar 216.
When the exhaust valve 12 is opened by the above-described regeneration operation, the compressed air in the case 20 passes through the exhaust pipe 215 and the collar 216 and is discharged from the exhaust port 112 opened at the lower end of the collar 216. At this time, since the compressed air is exhausted vigorously from the exhaust port 112 into the outside air, the air flow noise is suppressed by the silencers 217 and 218 so as not to cause a large noise around.

By the way, the desiccant 231 of the air dryer 11 deteriorates with use, and the adsorptive capacity after performing regeneration gradually decreases. Here, the deterioration of the desiccant 231 means that even if the desiccant 231 is regenerated, the compressed air supply system 1 cannot recover the adsorption capacity required for the desiccant 231 to a desired level. It means becoming. One cause of the deterioration of the desiccant 231 is that the compressor oil that flows into the air dryer 11 from the discharge pipe 41 of the compressor 4 adheres to the surface of the desiccant 231.
The desiccant 231 is made of a porous material such as silica gel. When oil adheres to the surface of the desiccant 231, countless holes on the surface of the desiccant 231 are blocked with oil, and the amount of moisture adsorbed decreases. In such a case, even if the desiccant 231 is regenerated, the adsorption capacity required for the desiccant 231 cannot be recovered, and it is necessary to replace it with a new one. On the other hand, since it takes cost and man-hours to replace the desiccant 231 of the air dryer 11, it is desirable to determine an appropriate replacement time and to minimize the replacement frequency.
Therefore, a humidity detection sensor is provided on the downstream side of the desiccant 231. The humidity detection sensor detects the humidity of the compressed air after the desiccant 231 is regenerated, and compares the detected value with a predetermined threshold value. Thus, the replacement time of the desiccant 231 can be determined. On the other hand, it has been proved by experiments that the detection value of the humidity detection sensor differs greatly depending on the environment (for example, air flow rate and ambient temperature) of the installation position of the sensor. In many cases, it is difficult to accurately determine the replacement time of the desiccant 231 based on the detection value of the sensor. Therefore, in the present embodiment, the threshold value can be changed and set according to the position where the humidity detection sensor is attached, and the detection of the humidity detection sensor is possible regardless of the attachment position of the humidity detection sensor. The replacement time of the desiccant 231 can be accurately determined from the value.

FIG. 3 is a schematic diagram showing each position where the humidity detection sensor is attached.
The loads 51 and 52 are the main brakes as described above. The main brakes include the brake valve 61 connected to the air tank 51a (51b) via the connecting pipe 60, and the connecting pipe 62 and the brake valve 61, respectively. And front brake chambers 64a and 64b and rear brake chambers 65a and 65b connected via a switch 63.
The brake valve 61 is provided with a brake pedal 61a for operating the brake valve 61. When the brake pedal 61a is depressed, the brake valve 61 is opened, and the compressed air in the air tank 51a (51b) is transferred to the front brake. The brakes are actuated by driving the brake shoes (not shown) guided to the chambers 64a and 64b and the rear brake chambers 65a and 65b.

In FIG. 3, a humidity detection sensor 14 is disposed in a supply path 106 that connects the air dryer 11 and the air tank 51 a (51 b), and this humidity detection sensor 14 is connected to the ECU 2 via a harness 66. Has been. Thereby, a signal indicating the detection value of the humidity detection sensor 14 is input to the ECU 2, and the ECU 2 acquires information regarding the humidity of the compressed air in the supply path 106 based on the input signal indicating the detection value.
The detection value of the humidity detection sensor 14 indicates the relative humidity value of the air in the supply path 106 and includes information related to temperature. The ECU 2 includes a display unit 67 that displays the detection value of the humidity detection sensor 14. As a specific configuration of the display unit 67, an LED that is switched on / off / flashing according to the detection value, and a detection value as a character And a liquid crystal display panel displaying with symbols and the like. The display unit 67 may be mounted in the passenger compartment together with the speedometer of the vehicle, or may be disposed in the vicinity of the compressor 4 and the air dryer 11 in the vehicle. With this display unit 67, a driver, a mechanic who maintains the vehicle, an administrator who manages the vehicle, etc. can visually recognize the detection value of the humidity detection sensor 14, and the replacement time of the desiccant 231 is appropriate. Can be judged.

In this configuration, the humidity detection sensor 14 includes (1) a supply path 106 that connects the air dryer 11 and the air tank 51a (51b), for example, (2) a tank central portion 70 of the air tank 51a (or 51b), (3) The tank inner surface 71 of the air tank 51a, (4) the brake valve 61, and (5) the connecting pipe 62 that connects the brake valve 61 and the front brake chamber 64a can be attached.
As described above, the detection value by the humidity detection sensor 14 varies greatly depending on the environment of the mounting position of the humidity detection sensor 14. Specifically, the detected humidity value varies greatly at a place where the air flow velocity is fast, and the detected humidity value is stable at a place where the air flow velocity is slow. Further, near the surface of the piping part or tank, the humidity value detected by the influence of the outside air temperature is likely to fluctuate. In this embodiment, as shown in FIG. 4, (1) a supply path 106 connecting the air dryer 11 and the air tank 51a (51b), (4) a brake valve 61, and (5) a brake valve 61 and a front brake When it is attached to the connecting pipe 62 that connects the chamber 64a, the air flow rate is high and it is easily affected by the outside air temperature. For this reason, when the humidity detection sensor 14 is provided at a position where the detected humidity value greatly fluctuates, the threshold value α for determining the deterioration of the desiccant 231 from the humidity value is a large value (for example, 80%). ).
On the other hand, (2) In the tank central portion 70 of the air tank 51a (or 51b), the flow rate of air is slow and it is not easily affected by the outside air temperature, so that the detected humidity value is stably output. For this reason, the threshold value β when the humidity detection sensor 14 is provided at a position where the detected humidity value is stable is set to a value (for example, 60%) sufficiently smaller than the above-described threshold value α. (3) Since the tank inner surface 71 of the air tank 51a has a slow air flow velocity but is also easily affected by the outside air temperature, the threshold value γ when the humidity detection sensor 14 is provided at this position is larger than the threshold value β. A value smaller than the threshold value α (for example, 70%) is set. These threshold values α to γ are reference threshold values when the outside air temperature is a reference temperature (for example, 25 ° C.), and the reference threshold value is corrected when the outside air temperature fluctuates.

In the present embodiment, since a threshold value corresponding to the position is set in the ECU 2 according to the position where the humidity detection sensor 14 is attached, the ECU 2 compares the threshold value with the humidity value detected by the humidity detection sensor 14. As a result, regardless of the mounting position of the humidity detection sensor 14, the replacement timing of the desiccant 231 can be accurately determined from the humidity value detected by the humidity detection sensor 14.
In the ECU 2, threshold values α to γ corresponding to the respective mounting positions (1) to (5) are stored in advance, and when the vehicle manufacturer or the vehicle mechanic attaches the humidity detection sensor 14 to the vehicle, By selecting an attachment position and inputting it to the ECU 2, a threshold value corresponding to the flow rate of the compressed air at the attachment position is set.

Next, the deterioration determination process for the desiccant 231 by the ECU 2 will be described with reference to FIG. Here, the humidity detection sensor 14 is demonstrated as what is provided in the supply path 106 which connects the air dryer 11 and the air tank 51a (51b).
First, the ECU 2 determines whether or not a preset regeneration timing has arrived (step S1). If it is not currently the regeneration timing (step S1: No), the ECU 2 determines whether or not the humidity value of the compressed air in the supply path 106 detected by the humidity detection sensor 14 is equal to or greater than a predetermined regeneration reference value set in advance. A determination is made (step S2). The regeneration reference value is a value that requires the regeneration of the desiccant 231 because the compressed air is not sufficiently dried by the desiccant 231. In this determination, when it is determined that the detected humidity value of the compressed air does not satisfy the predetermined regeneration reference value (No in step S2), the process returns to the determination in step S1. When it is determined that the humidity value of the compressed air is equal to or higher than the predetermined regeneration reference value (step S2: Yes), the ECU 2 regenerates the desiccant 231 by confirming the integrated ventilation amount of the air dryer 11, for example. The situation is confirmed (step S3).

Next, the ECU 2 checks the running state of the vehicle (step S4), and determines whether or not the desiccant 231 can be regenerated at present based on the running state of the vehicle (step S5). Specifically, the ECU 2 determines whether or not the vehicle is currently stopped, whether or not the pressure in the air tanks 51a and 52a is sufficient to regenerate the desiccant 231 set in advance. It is determined whether or not regeneration of the desiccant 231 is possible based on whether or not the brake assist operation is in progress.
Here, for example, when the vehicle is not stopped and the pressure in the air tanks 51a and 52a is sufficient to regenerate the desiccant 231, and further, the vehicle is not in the brake assist operation, It is determined that the desiccant 231 can be regenerated. On the other hand, when the pressure in the air tanks 51a and 52a is not sufficient to regenerate the preset desiccant 231 regardless of the running state of the vehicle, or when the vehicle is in a brake assist operation Is determined that the desiccant 231 cannot be regenerated.

  When it is determined in step S5 that the desiccant 231 can be regenerated at present (step S5: Yes), the ECU 2 regenerates the desiccant 231 regardless of a predetermined regeneration timing set in advance ( Step S6). Specifically, the ECU 2 opens the electromagnetic valve 102, and the compressed air stored in the downstream side of the air dryer 11 (for example, in the supply path 106 and the air tanks 51 a and 52 a) is used as the case 20 of the air dryer 11. The inside flows backward and is discharged from the exhaust port 112. As a result, air passing through the case 20 becomes super dry due to rapid pressure reduction, and moisture is taken away from the desiccant 231 in the case 20, so that the desiccant 231 is regenerated. Further, when it is determined in step S1 that a predetermined reproduction timing set in advance has arrived (step S1: Yes), the running state is also confirmed (step S4), and reproduction is possible (step S5). : Yes), the regeneration treatment of the desiccant 231 is performed (step S6).

Next, the ECU 2 acquires the outside air temperature, and corrects the threshold set corresponding to the flow rate of the compressed air at the mounting position of the humidity detection sensor 14 based on the outside air temperature (step S7). Here, the threshold value is a value used to determine the deterioration of the desiccant 231 (whether the adsorptive capacity required for the desiccant 231 has been recovered by regeneration) from the humidity value detected by the humidity detection sensor 14. Yes, it is set corresponding to the position where this humidity detection sensor 14 is attached.
Specifically, the ECU 2 stores a correction threshold value obtained by correcting a reference threshold value at a reference temperature (for example, 25 ° C.) by a change in the outside air temperature as a map associated with the outside air temperature, and a correction corresponding to the outside air temperature. Read and set the threshold. In this configuration, the relationship between the outside air temperature and the correction threshold value is such that if the outside air temperature increases, the correction threshold value changes greatly. If the outside air temperature decreases, the correction threshold value changes accordingly. Is set. As described above, since the threshold value is corrected based on the outside air temperature, it is possible to quickly cope with a change in season and weather, and it is possible to accurately determine the replacement time of the desiccant 231 in any weather condition.
In the present embodiment, the correction amount based on the temperature change is not constant depending on each of the threshold values α to γ. For the threshold value α set to a large value, the correction amount based on the temperature change is set to a large value and set to a small value. For the threshold value β, it is desirable to set the correction amount based on the temperature change small. According to this configuration, since the threshold corresponding to the mounting position of the humidity detection sensor 14 and the surrounding environment is set, the replacement time of the desiccant 231 can be determined more accurately.

Next, after regenerating the desiccant 231, the ECU 2 acquires the humidity value detected by the humidity sensor 14 and determines whether or not the desiccant 231 has deteriorated based on the humidity value (step S <b> 8). . Specifically, the ECU 2 determines whether or not the humidity value of the compressed air in the supply path 106 has fallen below the threshold value corrected in step S7.
If it is determined in step S8 that the humidity value of the compressed air has decreased below the corrected threshold value (step S8: Yes), it can be determined that the adsorptive capacity of the desiccant 231 has been recovered by regeneration. For this reason, the ECU 2 determines that the desiccant 231 has not deteriorated, outputs a determination value indicating that the desiccant 231 has not deteriorated, to the display unit 67, and the desiccant 231 has deteriorated on the display unit 67. Display corresponding to the case where it is not (step S9).

  On the other hand, if it is determined in step S8 that the humidity value of the compressed air has not fallen below the corrected threshold value (step S8: No), the adsorptive capacity required for the desiccant 231 is recovered even if regeneration is performed. Therefore, there is a high possibility that the desiccant 231 has deteriorated. For this reason, the ECU 2 determines that the desiccant 231 has deteriorated, outputs a determination value indicating that the desiccant 231 has deteriorated, to the display unit 67, and the desiccant 231 has deteriorated on the display unit 67. Display corresponding to the case (step S10). In this manner, in step S8, the ECU 2 functions as a deterioration determination unit that determines the deterioration of the desiccant 231.

  As described above, according to this embodiment, the air dryer 11 that is provided in the discharge line of the compressor 4 and removes moisture contained in the compressed air, and the desiccant 231 of the air dryer 11 are attached downstream. The humidity detection sensor 14 is provided, and the desiccant 231 is regenerated at a predetermined timing, and the detection value of the humidity detection sensor 14 after the desiccant 231 is regenerated is determined according to the mounting position of the humidity detection sensor 14. By comparing with the threshold value set corresponding to the flow rate of the compressed air at this position, the deterioration of the desiccant 231 can be determined regardless of the mounting position of the humidity detection sensor 14. The replacement time can be accurately determined.

  Further, according to the present embodiment, the threshold value is large when the humidity detection sensor 14 is mounted at a position where the flow rate of compressed air is high and the humidity value fluctuates greatly, the flow rate of compressed air is low, and the humidity value is stable. When the position is set to be small, it is set small, so that the deterioration of the desiccant 231 can be accurately determined, and the replacement time of the desiccant 231 can be accurately determined.

  Further, according to the present embodiment, the outside temperature detection sensor 5 for detecting the outside temperature is provided, and the threshold value is corrected according to the detected outside temperature, so that it is possible to respond quickly to changes in season and weather, The replacement time of the desiccant 231 can be accurately determined under any weather conditions.

  Further, according to the present embodiment, the correction amount is adjusted according to the magnitude of the flow rate of the compressed air, so that a threshold value can be appropriately set for each attachment position, and the replacement timing of the desiccant 231 can be more accurately set. I can judge.

The above-described embodiment shows one aspect to which the present invention is applied, and the present invention is not limited to the above-described embodiment. For example, the humidity detection sensor 14 includes (1) a supply path 106 connecting the air dryer 11 and the air tank 51a (51b), (2) a tank central portion 70 of the air tank 51a (or 51b), and (3) an air tank 51a. It is possible to attach to any one of the tank inner surface 71, (4) the brake valve 61, and (5) the connecting pipe 62 that connects the brake valve 61 and the front brake chamber 64a. Of course, it may be attached to the position.
In the present embodiment, when the threshold value is corrected, the correction threshold value stored in the ECU 2 in association with the outside air temperature is read and set. However, the ECU 2 calculates the correction threshold value based on the outside air temperature, It is good also as a structure which sets this value by calculating.

  Further, the load connected to the air dryer module 10 is not limited to the main brake device, the parking brake, and the accessories, and any device that uses compressed air may be connected. The configuration can be arbitrarily changed. Further, the vehicle to which the compressed air supply device for a vehicle of the present invention is applied is not particularly limited, and may be any of a large vehicle, a small vehicle, a special vehicle, a towing vehicle, a two-wheeled vehicle, or a three-wheeled vehicle. The form is arbitrary.

1 Compressed air supply system (Vehicle compressed air supply system)
2 ECU (regeneration means, deterioration determination means)
4 Compressor (Air compressor)
5 Temperature sensor (outside temperature sensor)
11 Air dryer 14 Humidity detection sensor 51-54 Load 102 Solenoid valve (regeneration means)
231 Desiccant

Claims (2)

In a vehicle compressed air supply device that includes an air compressor mounted on a vehicle and supplies compressed air discharged from the air compressor to a load of the vehicle,
An air dryer provided in a discharge line of the air compressor to remove foreign substances such as moisture contained in the compressed air; a humidity detection sensor attached downstream of the desiccant of the air dryer; and a desiccant of the air dryer Regenerating means at a predetermined timing, and the detected value of the humidity detection sensor after the desiccant is regenerated by the regenerating means corresponds to the flow rate of the compressed air at the mounting position of the humidity detecting sensor. And a deterioration determination means for determining whether or not the desiccant adsorption capacity is not recovered by the regeneration and determining the replacement timing of the desiccant, as compared with the set threshold value.
An outside air temperature detection sensor for detecting outside air temperature, a correction means for correcting the threshold according to the detected outside air temperature, an air tank capable of temporarily storing air from which foreign matter has been removed by the air dryer, and A brake device as the load to which the air in the air tank is supplied,
The humidity detection sensor includes a supply path connecting the air dryer and the air tank, a tank central portion of the air tank, a tank inner wall surface of the air tank, a brake valve of the brake device, a brake chamber of the brake device, and the It can be attached to any of the connecting pipes that connect the brake valve,
When the humidity detection sensor is attached to the tank inner wall surface of the air tank, a threshold value for determining deterioration of the desiccant from the detected humidity value is set, and the humidity sensor is attached to the center of the air tank. The humidity is greater than any of a supply path connecting the air dryer and the air tank, a brake valve of the brake device, and a connecting pipe connecting the brake chamber of the brake device and the brake valve. Set smaller than the threshold when the sensor is attached,
The deterioration determination unit is configured to set the detection value of the humidity detection sensor after the desiccant is regenerated by the regeneration unit to each threshold value set corresponding to the flow rate of compressed air at the mounting position of the humidity detection sensor. To determine when to replace the desiccant due to deterioration of the desiccant,
The vehicular compressed air supply apparatus , wherein the correction means adjusts a correction amount according to the flow velocity of the compressed air.   The threshold value is set to be large when the humidity sensor is attached at a position where the flow rate of the compressed air is fast, and is set small when attached to a position where the flow rate of the compressed air is slow. The compressed air supply device for a vehicle according to 1.

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