JP2017160803A - Electric air compression device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric air compression device capable of properly grasping a deterioration state of an air compressor.SOLUTION: An electric air compression device 20 comprises an air compressor 21 and a compressor controller 22. The compressor controller 22 comprises a discharge time measurement part 221 measuring a discharge time for which the air compressor 21 discharges compressed air into an air reservoir, an operating time measurement part 222 measuring an operating time of the air compressor, and a number of starts measurement part 223 measuring a number of starts of the air compressor. The compressor controller 22 comprises a display part 225 for notifying deterioration information including at least the discharge time measured by the discharge time measurement part 221, the total operating time measured by the operating time measurement part 222 and the total number of starts measured by the number of starts measurement part 223.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electric air compressor.

  Trains are equipped with devices such as air springs, doors, and brakes that operate using compressed air. Therefore, the train is provided with an electric air compressor that generates compressed air and an air reservoir that stores the generated compressed air.

  A train formed by a plurality of vehicles is provided with a plurality of electric air compressors in order to supply compressed air used by each vehicle. In addition, the electric air compressor generally includes a compressor controller and a plurality of air compressors.

  Inspection and maintenance of air compressor vehicle equipment are carried out at a period stipulated by laws and regulations. Therefore, it is necessary to replace the maintenance parts at the same time even if there is variation in the deterioration of the equipment. For this reason, even maintenance parts that originally do not need to be replaced may have to be replaced in accordance with the parts that are most deteriorated.

  In order to reduce unnecessary parts replacement at the time of maintenance, an operation method of the apparatus that suppresses variation in deterioration is required. For example, as a method for suppressing variation in deterioration of an air compressor, a method of switching an air compressor to be operated in consideration of a cumulative operation time of the air compressor is known (Patent Document 1).

JP 2002-89456 A

  In the control method of the air compressor disclosed in Patent Document 1, the air compressor to be operated is switched based on the accumulated operation time, and the air compressor having a short accumulated operation time is preferentially used, so that the variation in deterioration is reduced. Suppress. However, even air compressors having the same operation time may not be uniform in their usage status, and thus there may be variations in the state of deterioration.

  For example, the amount of compressed air necessary for train operation varies depending on the train operation status, such as the frequency of brake use and the number of times the door is opened and closed. For this reason, even if it is the same operation time, a normal train with many stoppages has a large progress degree of deterioration compared with an express train with few stoppages. In addition, since the amount of compressed air used for each vehicle is different even within the same knitting, even if the operation time is the same, the deterioration state of the air compressor varies.

  Therefore, the deterioration state cannot be grasped based only on the cumulative operation time of the air compressor, and it is difficult to effectively suppress variation in deterioration.

  The present invention has been made in view of the above-described circumstances, and by grasping the deterioration state of the air compressor, the electric air compression capable of suppressing variation in deterioration and reducing unnecessary parts replacement due to maintenance. An object is to provide an apparatus.

  In order to achieve the above object, an electric air compressor according to the present invention includes an air compressor and a compressor controller. The compressor controller measures a discharge time measuring means for measuring the discharge time when the air compressor discharges compressed air, an operating time measuring means for measuring the operating time of the air compressor, and measures the number of times the air compressor is started. And a start count measuring means. In addition, the compressor controller reports at least deterioration information including the discharge time measured by the discharge time measuring means, the cumulative operating time measured by the operating time measuring means, and the cumulative start count measured by the start count measuring means. Informing means is provided.

  According to the present invention, since the deterioration state of the air compressor provided in the vehicle can be grasped, it is possible to suppress variation in deterioration of the air compressor and reduce parts replacement due to maintenance.

It is the schematic which shows the vehicle provided with the electric air compression apparatus which concerns on embodiment of this invention. It is a block diagram which shows the structure of the electric air compression apparatus which concerns on embodiment. It is a figure which shows the hardware constitutions of a compressor controller. It is a flowchart which shows the flow of a process of a compressor controller. It is a figure which shows the example of a display of the deterioration information of an air compressor. It is a flowchart which shows the starting order of an air compressor. It is a figure which shows the example of a display of the deterioration information in a monitor on a vehicle, FIG. 7 (A) is a figure of a simple display, FIG.7 (B) is a figure of a detailed display. It is a figure which shows the example of a display of the deterioration information in a compressor information database. It is a figure which shows the example of a display of the deterioration information which concerns on Embodiment 2, FIG. 9 (A) is a figure which shows the example of a display in an electric air compressor, FIG.9 (B) shows the example of a display on a vehicle monitor. FIG.

  Hereinafter, an electric air compressor according to an embodiment of the present invention will be described with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, a train 10 equipped with an electric air compressor 20 according to the present embodiment includes n vehicles (n is an integer of 2 or more) connected to each other (11-1 to 11-). n). The train 10 includes an electric air compressing device 20 that creates compressed air and an original air reservoir 30 for accumulating the compressed air discharged from the electric air compressing device 20 every other vehicle 11. In addition, the train 10 has a through pipe 36 that is drawn into the train to supply compressed air, a supply air reservoir 32 that supplies a compressor to the brake, a brake unit 33 that operates by compressed air, and a door that uses compressed air. A door opening and closing device 34 that opens and closes the vehicle, an air spring 35 that supports the vehicle with compressed air, an on-board monitor 40 that monitors information on the air compressor in the train 10, and a compressor information database 42 that is ground equipment. An antenna 41 is provided.

  The original air reservoir 30 is connected by a through pipe 36 drawn through the entire train 10, and is configured to supply the accumulated compressed air to each device operated by the compressed air. Further, as shown in FIG. 2, the original air reservoir 30 includes a pressure sensor 31 that detects the pressure in the original air reservoir 30.

  A supply air reservoir 32 shown in FIG. 1 is provided in each vehicle 11 and is connected to a through pipe 36. The supply air reservoir 32 accumulates compressed air supplied through the lead-in pipe 36 and supplies the compressed air to the brake unit 33.

  Furthermore, the door opening / closing device 34 and the air spring 35 included in the vehicle 11 are connected to the through pipe 36 and operate using compressed air.

  As shown in FIGS. 1 and 2, the on-board monitor 40 is provided in the leading vehicle 11-1 of the train 10, and is electrically connected to each electric air compressor 20 through the transmission / reception unit 403. The on-vehicle monitor 40 includes a display unit 401 including a liquid crystal display panel, an EL (Electro Luminescence) display panel, and the like, and displays deterioration information received from each air compressor 21. The on-board monitor 40 includes a touch panel attached to the display unit 401 as the input unit 402, a transmission / reception unit 403 that communicates with an external device, and a control unit 404 that controls the operation of the entire on-board monitor 40.

  An antenna 41 shown in FIG. 1 is provided in the leading vehicle 11-1 of the train 10, and is used for wireless communication in order to exchange information with the compressor information database 42 that is ground equipment. . As the wireless communication, for example, train radio such as a space wave radio system or an LCX system can be used, but is not limited thereto.

  The compressor information database 42 is a database for managing deterioration information of the air compressor 21 of each train 10. The compressor information database 42 includes a display unit 501 (not shown) for displaying deterioration information of the air compressor 21 received from each train 10.

  As shown in FIG. 2, each electric air compressor 20 includes three air compressors 21 (21-1 to 21-3) and a compressor controller 22.

  The compressor controller 22 includes a discharge time measurement unit 221 that measures the discharge time of compressed air, an operation time measurement unit 222 that measures the operation time of the air compressor 21, and an activation frequency measurement that measures the activation frequency of the air compressor 21. Unit 223, a storage unit 224 that stores information about the air compressor 21, a display unit 225 that displays information about the air compressor 21, an input unit 226 that inputs setting values related to the operation of the air compressor 21, an on-board monitor 40, Are provided with a first transmission / reception unit 227 for transmitting / receiving information to / from the compressor, a second transmission / reception unit 228 for transmitting / receiving information to / from the compressor information database 42, and an operation control unit 229 for controlling the operation of the air compressor 21.

  The discharge time measurement part 221 measures the discharge time of compressed air about each of the air compressors 21-1 to 21-3. The discharge time means a time during which the compressed air is discharged in the operating state.

  The operating time measuring unit 222 measures the operating time for each of the air compressors 21-1 to 21-3. The operating time means the time from when the air compressor 21 starts up until it stops.

  The activation count measuring unit 223 measures the activation count for each of the air compressors 21-1 to 21-3.

  The storage unit 224 stores operation programs, measurement data, and the like.

  The display unit 225 includes a display panel and displays information regarding the air compressor 21, particularly information indicating a deterioration state.

  The input unit 226 inputs a set value related to the operation of the air compressor 21.

  The first transmission / reception unit 227 transmits / receives information to / from the on-board monitor 40.

  The second transmitter / receiver 228 transmits / receives information to / from the ground station via the antenna 41 for exchanging information with the compressor information database 42.

  The operation control unit 229 controls the air compressors 21-1 to 21-3 and also controls the operation of the compressor controller 22 as a whole.

  The compressor controller 22 shown in FIG. 2 physically has, for example, a hardware configuration shown in FIG. Specifically, the compressor controller 22 includes a CPU (Central Processing Unit) 231 that controls the entire apparatus, a storage unit 232 that stores an operation program of the CPU 231, and an input unit 233 that inputs instructions and data. A display unit 234 for displaying data, a wireless communication unit 235 for wireless communication with an external device, an input / output I / F (interface) 236 for transmitting data to and from the external device, and a bus 237 for connecting them. .

  The storage unit 232 includes a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, and the like. The storage unit 232 functions as a work area of the CPU 231 and also has an operation program for causing the CPU 231 to function as the compressor controller 22. Store the data.

  Specifically, the storage unit 232 stores an air compressor control program 232a, a discharge time measurement program 232b, and control data 232c.

  The air compressor control program 232a is a program for executing processing for controlling the air compressors 21-1 to 21-3 as the operation control unit 229, as will be described later with reference to FIGS. In addition, the air compressor control program 232a includes a program for executing a process of measuring the operation time and the number of activations as the operation time measurement unit 222 and the activation number measurement unit 223.

  The discharge time measurement program 232b is a program that causes the CPU 231 to execute processing for measuring the time during which the air compressors 21-1 to 21-3 discharge compressed air.

  The control data 232c is data used for control, such as data acquired from the pressure sensor 31 and various threshold values. The control data 232c also includes data such as the measured discharge time, cumulative operation time, and cumulative activation count.

  The input unit 233 functions as the input unit 226 and inputs various data. The display unit 234 is a device that functions as part of the display unit 225. The input unit 233 and the display unit 234 may be configured by a touch panel or the like, and may have both an input function and a display function.

  The wireless communication unit 235 functions as the second transmission / reception unit 228.

  The input / output I / F 236 is a device that communicates between the external device and the compressor controller 22, transmits instructions / data from the CPU 231 to the external device, and receives commands and data provided from the external device. Captured and provided to the CPU 231. The external device includes air compressors 21-1 to 21-3, a vehicle monitor 40, a pressure sensor 31 disposed in the original air reservoir 30, and a sensor group such as a timer.

  The CPU 231 executes a program stored in the storage unit 232 and realizes each functional unit shown in FIG.

  Next, the flow of processing executed by the compressor controller 22 will be described with reference to FIG. The electric air compressor 20 sets the starting order of the air compressors 21 and sets a lower limit pressure that is a trigger for starting each air compressor 21. However, details regarding the setting of the activation order will be described later, and a basic processing flow will be described here.

  The operation control unit 229 acquires the pressure in the original air reservoir 30 based on the output from the pressure sensor 31 (S11). The operation control unit 229 determines whether or not the acquired pressure in the original air reservoir 30 is lower than the lower limit pressure (S12). Here, the lower limit pressure refers to a pressure to be maintained in order to stably operate various devices. Moreover, the upper limit pressure set for the original air reservoir 30 to safely store the compressed air is referred to as the upper limit pressure.

  When the pressure in the original air reservoir 30 is lower than the lower limit pressure due to the use of compressed air by a brake operation, a door opening / closing operation or the like (S12; YES), the operation control unit 229 reduces the pressure in the original air reservoir 30. In order to recover above the lower limit pressure, an operation command is sent to the air compressor 21 to start the air compressor 21 (S13).

  Further, the operation control unit 229 transmits the activation information of the air compressor 21 to the activation number measurement unit 223 and the operation time measurement unit 222. Upon receiving the activation information, the activation number measuring unit 223 updates the accumulated activation number (S14). For example, when the air compressor 21-1 is activated, the activation number measurement unit 223 reads the accumulated activation number Cs before activation of the air compressor 21-1 from the storage unit 224.

  Next, the activation number measuring unit 223 records the accumulated activation number Cs updated by adding the current activation amount in the storage unit 224 and transmits it to the display unit 225 as a notification unit.

  Further, the activation count measuring unit 223 compares the threshold Thc that is determined in advance and stored in the storage unit 224 with the updated accumulated activation count Cs, and the accumulated activation count exceeds the threshold (Cs> In Thc), the warning information Ac is transmitted to the display unit 225.

  Moreover, the operating time measurement part 222 will start the measurement of an operating time, if the said starting information is received (S21). For example, when the air compressor 21-1 is activated, the operation time measurement unit 222 reads the accumulated operation time from the storage unit 224 until the air compressor 21-1 is activated. Thereafter, the accumulated operation time Tr is calculated by adding the operation time after activation.

  The operating time measuring unit 222 updates the accumulated operating time information at a predetermined update cycle. For example, the cumulative operating time calculated every 30 minutes is recorded in the storage unit 224 and transmitted to the display unit 225. In addition, the operating time measuring unit 222 compares a threshold value Thr that is determined in advance and stored in the storage unit 224 with the calculated cumulative operating time Tr, and when the cumulative operating time exceeds the threshold value (Tr> Thr). ), The warning information Ar is transmitted to the display unit 225.

  The activated air compressor 21 starts generating compressed air. The operation control unit 229 monitors whether or not the pressure of the air compressor 21 has reached a dischargeable pressure (S22). When the air compressor 21 is in a state capable of discharging compressed air (S22; YES), discharge is started (S23), and discharge start information is transmitted to the discharge time measuring unit 221. Upon receiving the discharge start information, the discharge time measurement unit 221 starts measuring the discharge time for each air compressor 21 (S24).

  The operation control unit 229 determines whether or not the air pressure in the original air reservoir 30 has reached the upper limit pressure by filling with compressed air (S31). When the pressure in the original air reservoir 30 rises to the upper limit pressure (S31; YES), a stop command is sent to the air compressor 21 to stop the discharge of compressed air (S32), and discharge stop information is sent to the discharge time measuring unit 221. Send. Upon receiving the discharge stop information, the discharge time measuring unit 221 stops the discharge time measurement and calculates the discharge time Td for each air compressor 21 (S33).

  The discharge time measurement unit 221 records the measured discharge time in the storage unit 224 and transmits it to the display unit 225 every time discharge stops. Further, the discharge time measuring unit 221 compares a threshold Thd that is determined in advance and held in the storage unit 224 with the calculated discharge time Td, and when the discharge time exceeds the threshold (Td> Thd). Transmits the warning information Ad to the display unit 225. This is because, as the air compressor 21 deteriorates, the amount of compressed air discharged decreases, and the discharge time required to recover the pressure in the original air reservoir 30 increases.

  Further, the operation control unit 229 stops the air compressor 21 when the pressure in the original air reservoir 30 reaches the upper limit pressure (S34). When the air compressor 21 is stopped, the operation control unit 229 transmits operation stop information to the operation time measuring unit 222. When receiving the operation stop information, the operation time measuring unit 222 stops measuring the operation time, calculates the accumulated operation time up to that point, and stores it in the storage unit 224 (S35).

  The display unit 225 displays information on the deterioration state of each air compressor 21 based on the data Cs, Tr, Td received from the activation number measuring unit 223, the operation time measuring unit 222, and the discharge time measuring unit 221. . The display unit 225 includes, for example, a liquid crystal panel, and displays deterioration information including a discharge time, a cumulative operation time, and a cumulative activation number for each air compressor 21 as illustrated in FIG.

  Thereby, about the air compressor 21 in the electric air compressor 20, it can be grasped which air compressor 21 is being deteriorated. When the warning information Ac, Ar, Ad is received from each measurement unit, the display unit 225 displays an item to be warned in the alarm item. For example, according to FIG. 5, [operating time] is displayed in the alarm section of the compressor C1, and it can be easily understood that the cumulative operating time of the compressor C1 exceeds the threshold of 4000 hours. .

  By referring to the deterioration information of the air compressor 21, it is possible to suppress variations in the deterioration state by using the activation order setting function provided in the compressor controller 22. The method will be described below.

  The activation order is set by a touch panel attached to the display unit 225 as the input unit 226. Thereby, the starting order of the air compressor 21 in the electric air compressor 20 can be set based on the displayed deterioration information. Information on the set activation order is recorded in the storage unit 224.

  Before starting the air compressor 21, the operation control unit 229 refers to the start order information recorded in the storage unit 224, and sends an operation command to the air compressor 21 in the set start order.

  5 and FIG. 6 as an example, instead of the above lower limit pressure, the first lower limit pressure, the second lower limit pressure lower than the first lower limit pressure, and lower than the second lower limit pressure. A three-stage pressure value called a third lower limit pressure is set in advance. And the step of said S12 and S13 at the time of starting of the air compressor 21 is determined according to the flow of FIG.

  When the pressure in the original air reservoir 30 falls below the first lower limit pressure (S41; YES), the compressor C3 whose start order is 1 is started (S42). Furthermore, when the pressure in the original air reservoir 30 is lower than the second lower limit pressure (S43; YES), in addition to the compressor C3, the compressor C2 whose starting order is 2 is also started (S44). When the pressure in the original air reservoir 30 is lower than the third lower limit pressure (S45; YES), all the air compressors 21 of the compressors C1, C2, and C3 are started (S46).

  As a result, it is possible to preferentially operate the air compressor 21 that has not progressed deterioration, and to suppress variations in the deterioration state between the air compressors.

  Further, in the present embodiment, the deterioration information of each air compressor 21 is configured to be transmitted to the on-board monitor 40, and the variation suppression of the air compressor 21 by the activation order setting is also performed on the on-board monitor 40. It can be carried out.

  The first transmission / reception unit 227 of the compressor controller 22 receives deterioration information including the latest discharge time, cumulative operation time, and cumulative number of activations for each air compressor 21 recorded in the storage unit 224, for example, every 10 minutes. It transmits to the on-board monitor 40 (FIG. 2).

  The on-board monitor 40 displays information on the deterioration state of each air compressor 21 on the display unit 401 based on the deterioration information received from the compressor controller 22. As shown in FIG. 7A, for each electric air compressor 20, the data of the air compressor 21 that is most deteriorated in the electric air compressor 20 is selected and displayed for each item.

  More specifically, in the column of the air compressor D1 in the display example shown in FIG. 7A, the discharge time of the compressor C1 and the cumulative operating time of the compressor C2 shown in the detailed information of FIG. The data of the cumulative number of activations is selected and displayed as data of the air compressor 21 that is most deteriorated. Further, the simple display of FIG. 7A and the detailed display of FIG. 7B can be selected and displayed. Thereby, the state of deterioration can be easily grasped about the electric air compressor 20 in the train 10.

  Further, the compressor controller 22 transmits warning information Ac, Ar, Ad together with the deterioration information to the on-board monitor 40. When the warning information is received, the display unit 401 displays an item to be warned in the alarm item. For example, in FIG. 7A, [Discharge time] and [Number of activations] are displayed in the alarm section of the air compressor D1, and the discharge time and the cumulative number of activations of the air compressor 21 in the air compressor D1 are displayed. Can easily be understood as exceeding a predetermined threshold.

  The start order setting function of the on-board monitor 40 is different from the start order setting function provided in the compressor controller 22 in that the start order for each electric air compressor 20 can be set.

  The setting is performed by inputting the activation sequence of the electric air compressor 20 in the train 10 on the simplified display screen of FIG. 7A by using a touch panel attached to the display unit 401 as the input unit 402. In FIG. 7A, the activation order is set for the air compressors D1 to D3 included in the train T1 as the train 10.

  Information on the set activation order is recorded in the storage unit 224 of each compressor controller 22 via the first transmission / reception unit 227.

  Before starting the air compressor 21, the operation control unit 229 refers to the information on the start order recorded in the storage unit 224 and starts the operation of the air compressor 21 according to the set start order.

  An example of the activation method according to the setting of the activation order will be described with reference to FIG. 7A. As the lower limit pressure in the original air reservoir 30, the second lower limit pressure is lower than the first lower limit pressure and the first lower limit pressure. A three-stage pressure value is set in advance, which is a lower limit pressure and a third lower limit pressure lower than the second lower limit pressure. Then, when the pressure in the original air reservoir 30 falls below the first lower limit pressure, only the air compressor D3 whose activation order is 1 is activated. Further, when the pressure in the original air reservoir 30 falls below the second lower limit pressure, the air compressor D2 whose start sequence is 2 is started in addition to the air compressor D3. Moreover, when the pressure in the original air reservoir 30 falls below the third lower limit pressure, all the electric air compressors 20 of the air compressors D1, D2, and D3 are activated.

  As a result, it is possible to preferentially operate the electric air compressor 20 that has not deteriorated, and to suppress variations in the deterioration state between the air compressors.

  In addition, the activation order setting input from the input unit 226 of the compressor controller 22 and the activation order setting input from the input unit 402 of the on-board monitor 40 may be any one by setting the lower limit pressure individually. The activation order setting function can also be enabled, but an exclusive setting that gives priority to any activation order setting function can also be used.

  Moreover, in this Embodiment, the compressor controller 22 is comprised so that the deterioration information of each air compressor 21 may be transmitted to the compressor information database 42, and the air compressor 21 is based on this deterioration information. It is also possible to suppress variation in deterioration of the material.

  The compressor controller 22 sends the deterioration information including the latest discharge time, the accumulated operation time, and the accumulated number of activations for each air compressor 21 recorded in the storage unit 224 via the second transmission / reception unit 228, for example, 10 minutes. Each time it is sent to the compressor information database 42.

  The compressor information database 42 displays information on the deterioration state of each air compressor 21 on the display unit 501 based on the deterioration information received from the compressor controller 22. As shown in FIG. 8, the display unit 501 selects and displays, for each item, data of the air compressor 21 that is most deteriorated in the train 10 for each train 10 train.

  More specifically, in the column of the formation T1 in FIG. 8, the data of the discharge time, the accumulated operation time, and the accumulated number of activations of the air compressor 21 that is most deteriorated among the air compressors 21 provided in the train 10 are displayed. Is selected and displayed. Moreover, you may enable it to select and display the detailed display in which the deterioration information of all the air compressors 21 is displayed like FIG. 7 (B). Thereby, the deterioration state of the air compressor 21 can be easily grasped about the train 10 operated by the company.

  The compressor controller 22 may transmit warning information Ac, Ar, Ad together with the deterioration information to the compressor information database 42. When the warning information is received, the display unit 501 displays an item to be warned in the alarm section. In the example shown in FIG. 8, [Discharge time] and [Number of activations] are displayed in the alarm section of the formation T1, and the discharge time and the cumulative number of activations of the air compressor 21 mounted on the formation T1 are set in advance. It can be easily grasped that the predetermined threshold is exceeded.

  The display unit 501 also displays information on the current operation status for each train 10, that is, whether the train is a regular train or a limited express train at each station. When the train is operated by an express train, the number of times the brake is used and the number of times the door is opened and closed is smaller than when the train is an ordinary train, so that the amount of compressed air used is small. Therefore, the number of times of starting the air compressor 21 is relatively small, and the deterioration is difficult to proceed. From this, it becomes possible to set the next operation plan in consideration of the operation status of each organization displayed on the display unit 501 and the deterioration information of the air compressor 21.

  Thereby, the train in which the deterioration of the air compressor 21 has not progressed is a normal train, and the train in which the deterioration has progressed is an express train, thereby suppressing variations in the deterioration state of the air compressor 21 between trains. Can do.

  As described above, according to the electric air compressor 20 according to the present embodiment, it is possible to easily grasp the deterioration state of each air compressor 21. Further, since the train can be operated in consideration of the deterioration information, variation in deterioration of the air compressor 21 can be suppressed, and unnecessary parts replacement due to maintenance can be reduced.

(Embodiment 2)
Next, an electric air compressor according to Embodiment 2 of the present invention will be described. The electric air compressor 20 and the on-board monitor 40 according to the present embodiment are different from the first embodiment in that they have a timer function for setting the start timing of the air compressor 21.

  Specifically, the compressor controller 22 has a timer function. The timer function is set by inputting a waiting time until an operation instruction is sent for each air compressor 21 in the electric air compressor 20 using a touch panel as the input unit 226 provided in the display unit 225. For example, as shown in FIG. 9A, by setting a timer so that the compressor C3, which has a short discharge time and relatively not deteriorated, is started first, the air compressor 21 that has not deteriorated is set. It becomes possible to operate preferentially, and it is possible to suppress variation in the deterioration state between the air compressors.

  Furthermore, the on-board monitor 40 has a timer function for setting the activation time. The timer function sets a waiting time until the air compressor 21 is activated for each electric air compressor 20 in the train 10 using a touch panel as the input unit 402. For example, as shown in FIG. 9B, by setting a timer so that the air compression device D3, which has a short discharge time and relatively not deteriorated, is started first, electric air compression that has not deteriorated It becomes possible to operate the apparatus 20 preferentially and to suppress the variation in the deterioration state between the air compressors.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and applications are possible.

  The electric air compressor 20 described above includes the three air compressors 21, but is not limited thereto. For example, only one air compressor 21 may be provided in the electric air compressor 20.

  Moreover, although the compressor controller 22 performed transmission of the deterioration information to the compressor information database 42, it may be performed by the on-board monitor 40. Thereby, since the 2nd transmission / reception part 228 can be provided in the on-board monitor 40, it becomes possible to simplify the structure of the compressor controller 22. FIG.

  Further, in the above-described embodiment, the user performs the next maintenance timing based on the displayed cumulative activation number Cs, cumulative operation time Tr, discharge time Td, warning information Ac, Ar, Ad, and the like. Predicting the degree of deterioration of each device, we examined the necessity for replacement and repair.

  The present invention is not limited to this embodiment. You may comprise so that the compressor controller 22 may anticipate the necessity of replacement | exchange of each apparatus by this maintenance.

  For example, it is assumed that the cumulative number of activations at the time of the current maintenance is Cs0, the cumulative operation time is Tr0, and the latest discharge time is Td0, all of which are less than the threshold value.

  In this case, for example, the compressor controller 22 obtains the evaluation value EV by the evaluation formula shown by the following formula, and when the evaluation value EV is equal to or higher than the reference value, the display unit is configured to perform replacement or repair in the current maintenance. 225, an alarm may be displayed on the on-board monitor 40 or the like.

なお、ｋ１、ｋ２、ｋ３は係数。Ｔｈｃ、Ｔｈｒ、Ｔｈｄは閾値。

K1, k2, and k3 are coefficients. Thc, Thr, Thd are threshold values.

  In addition, when a sufficient amount of past performance data has been accumulated, a value measured by the next maintenance timing is predicted, compared with each threshold value, and the predicted value is greater than the threshold value. In this case, the apparatus or device may be replaced or repaired in this maintenance.

  Alternatively, the measurement values Cs, Tr, Td and their acquisition date / time may be stored in association with each other, and the values Cs, Tr, Td at the time of the next maintenance may be predicted using an approximate curve. Then, the predicted values Cs, Tr, and Td are compared with the threshold values Thc, Thr, and Thd. For example, when even one increases, a notification is made that replacement or repair is necessary for the current maintenance. Also good.

  In the above embodiment, three parameters of the cumulative activation number Cs, the cumulative operation time Tr, and the discharge time Td are shown as parameters indicating the deterioration of the air compressor 21. However, other parameters may be measured and used. Good. Also, only two of the parameters may be used instead of all three.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. The above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. In other words, the scope of the present invention is indicated by the scope of claims, not the embodiment described above. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

DESCRIPTION OF SYMBOLS 10 Train, 11 Vehicle, 20 Electric air compressor, 21 Air compressor, 22 Compressor controller, 30 original air reservoir, 31 Pressure sensor, 32 Supply air reservoir, 33 Brake part, 34 Door opening and closing device, 35 Air spring, 36 Passing tube, 40 On-board monitor, 41 Antenna, 42 Compressor information database, 221 Discharge time measuring unit, 222 Operating time measuring unit, 223 Start-up number measuring unit, 224 Storage unit, 225 Display unit, 226 Input unit, 227 First transmission / reception unit, 228 Second transmission / reception unit, 229 Operation control unit, 231 CPU, 232 storage unit, 232a Air compressor control program, 232b Discharge time measurement program, 232c control data, 233 input unit, 234 display unit, 235 wireless Communication unit, 236 input / output I / F, 237 bus, 401 display unit, 402 Input unit, 403 transceiver unit, 404 control unit.

Claims (7)

An air compressor and a compressor controller;
The compressor controller is
A discharge time measuring means for measuring a discharge time during which the air compressor discharges compressed air; and
An operating time measuring means for measuring the operating time of the air compressor;
An activation number measuring means for measuring the activation number of the air compressor;
Notification means for notifying deterioration information including at least the discharge time measured by the discharge time measurement means, the cumulative operation time measured by the operation time measurement means, and the cumulative number of activations measured by the activation number measurement means;
An electric air compression apparatus comprising: The compressor controller is
The electric air compressor according to claim 1, wherein warning information is notified when any of the discharge time, the cumulative operation time, and the cumulative number of activations exceeds a predetermined threshold. The compressor controller is
3. The deterioration information for each of the air compressors is reported for each of the plurality of air compressors included in the electric air compressor, by measuring each discharge time, operation time, and number of activations. Electric air compressor. The compressor controller is
The electric air compressor according to claim 3, wherein the air compressor in the electric air compressor is started in accordance with a preset starting order. The compressor controller is
The electric air compressor according to claim 3 or 4, wherein the air compressor in the electric air compressor is started according to a preset start time. The compressor controller is
The electric air compressor according to any one of claims 1 to 5, wherein the deterioration information is transmitted to an on-board monitor provided on a train including the electric air compressor. The compressor controller is
The electric air compressor according to any one of claims 1 to 6, wherein the deterioration information is transmitted to a deterioration information database provided on the ground.

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