JP2000234987A - Inspection support system of machine facilities - Google Patents

Abstract

PROBLEM TO BE SOLVED: To appropriately carry out the preventive conservation work of machine facilities in site without allowing a specialist in preventive conservation to visit the site. SOLUTION: A terminal 10 of a specialist being installed in the whereabouts of an inspection specialist is connected to a terminal 20 in site being installed in site where machine facilities 40 to be inspected are provided by a communication line 30. The terminal 10 of the specialist is equipped with a function that obtains inspection support information required for the inspection of the machine facilities 40 by input from an input part 11 or generation inside, a function that sends the inspection support information to the terminal 20 in site, and a function that stores inspection result information being sent from the terminal 20 in site into a storage part 12 for performing external output such as display output. The terminal 20 in site is equipped with a function that stores the inspection support information being sent from the terminal 10 of the specialist into a storage part 21 for performing the external output such as the display output, and a function that receives the input of the inspection result information regarding the inspection result of the machine facilities 40 for sending to the terminal 10 of the specialist.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inspection support system for mechanical equipment, and more particularly to an inspection, repair, and part replacement for preventive and maintenance of mechanical equipment such as a pump, a compressor, a fan and a blower. The present invention relates to an inspection support system used when performing the inspection.

[0002]

2. Description of the Related Art Mechanical equipment with power, such as a pump, a compressor, a fan and a blower, is disturbed in the maintenance state of the equipment due to the influence of vibrations and the like during daily operation. For this reason, regular inspection of the maintenance state is required, and depending on the inspection result, repair or replacement of parts is also required. However, a large-scale mechanical equipment is composed of many parts, and even one mechanical equipment has irregularities in the maintenance state depending on the part.

[0003] For example, a part that is subjected to stronger vibration every day suffers from an irregular maintenance state and the deterioration of members is severe, while a part with relatively weak vibration is more irregular in the maintenance state and deterioration of the parts than those parts. is there. In addition, a plurality of machinery and equipment are installed in the factory, and the total number of inspection locations is enormous. For this reason, it is efficient to perform appropriate inspections and repairs only on the parts that need maintenance, and omit inspections on parts that do not need maintenance yet.

[0004] For this reason, conventionally, inspection is entrusted to a specialist for prevention and maintenance of mechanical equipment, and the expert examines the last inspection time, the inspection result, the presence of the last repair, the presence of the last part replacement, and the like. Based on this information and past experience, the next appropriate inspection time and inspection content were scheduled for each part of the machinery and equipment, and efficient inspection and preventive maintenance work were performed.

[0005]

However, the work of preventive maintenance specialists is often based on experience, and it is difficult to train such engineers within the company at present. Under such circumstances, there are many cases where an external preventive maintenance specialist is requested to perform an inspection, and then an expert visits the site to respond to the inspection. For this reason, there is a disadvantage that the cost required for the inspection is excessive, and it is not possible to immediately respond when it is necessary to perform the inspection or repair.

SUMMARY OF THE INVENTION An object of the present invention is to improve the disadvantages of the prior art and, in particular, to provide a machine capable of performing appropriate preventive maintenance work on machinery and equipment at a site without requiring an expert to visit the site. An object of the present invention is to provide a facility inspection support system.

[0007]

In order to achieve the above object, an inspection support system for mechanical equipment according to the present invention includes an expert terminal installed at the location of an inspection expert and mechanical equipment to be inspected. A site terminal to be installed at a given site, the site terminal and the expert terminal are connected by a communication line, and the expert terminal provides inspection support information necessary for the inspection of the mechanical equipment from the input unit. Inspection support information acquisition function to obtain by input or generation inside, inspection support information transmission function to transmit the inspection support information to the site terminal, and test result information transmitted from the site terminal stored in the storage unit A test result providing function of performing an external output such as a display output; and the site terminal stores the test support information transmitted from the expert terminal in a storage unit and performs an external output such as a display output. A support information providing function, characterized in that it comprises a test and result information transmitting function of transmitting the mechanical test results the test result information accepting input of information about the test results of equipment to the expert terminal.

Here, the inspection support information means information necessary for performing inspection when performing preventive and maintenance work of mechanical equipment such as a pump, a compressor, a fan and a blower. Inspection schedule information indicating an inspection schedule, inspection procedure information indicating an inspection procedure of mechanical equipment, and the like are included. In addition, the inspection result information, based on the above-described inspection support information, means information about the result of the inspection of the mechanical equipment, the inspection result of the mechanical equipment using measuring equipment, such as vibration waveforms in rotating equipment In addition to data and the like, information such as repair and replacement of parts and the like constituting the mechanical equipment is also included.

Then, the examination schedule information described above,
The inspection procedure information is configured taking into account not only the inspection results of the mechanical equipment but also information such as repairs and parts replacement based on the inspection results. According to the present invention, the inspection support information, the inspection result information, and the like are exchanged between the expert terminal and the site terminal via the communication line. Even if an expert does not visit the site, the expertise can be provided to the site, and the cost for the preventive and maintenance work can be reduced and the preventive and maintenance work can be quickly performed.

[0010] In the above, the inspection support information described above is:
It is preferable to include the inspection schedule information. That is, since the inspection support information is configured to include the inspection schedule information, it is possible to inspect the machinery and equipment in accordance with the schedule based on the inspection schedule information at the site without the presence of an expert. Inspect at the right time to prevent machinery and equipment,
Maintenance work can be performed.

It is preferable that the above-mentioned inspection support information includes inspection procedure information. That is,
Since the inspection support information is configured to include the inspection procedure information, it is possible to inspect the machinery and equipment according to the procedure based on the inspection procedure information on site without the presence of an expert,
Without requiring specialized knowledge, the person in charge at the site can carry out inspections in an appropriate procedure and perform preventive and maintenance work on mechanical equipment.

Further, the above-mentioned expert terminal preferably has an automatic schedule function for calculating inspection schedule information based on the inspection result information. That is,
An automatic schedule function that calculates inspection schedule information is provided, so that the next inspection schedule can be set according to the date of the last inspection included in the inspection result information and the fact that parts were repaired or replaced based on the previous inspection. It can be automatically set, and the effort of the schedule preparation work of the preventive and maintenance specialists performed on the specialist terminal can be reduced.

In the case where the above-mentioned field terminal has a vibration waveform data acquisition function for acquiring vibration waveform data of mechanical equipment as inspection result information, the expert terminal transmits the vibration waveform data to a preset abnormality diagnosis. The frequency analysis processing may be performed on the vibration waveform data when the abnormality is detected in the vibration waveform data from the comparison result with the threshold data. That is, since the expert terminal compares whether the vibration waveform data from the site terminal is the abnormality diagnosis threshold or not, it is not necessary to perform the frequency analysis process when no abnormality is found in the vibration waveform data, Unnecessary calculation load can be eliminated.

It is preferable to use a public line as the above-mentioned communication line. For example, it is preferable to connect an expert terminal and a site terminal using the Internet or the like. That is, if the expert terminal and the on-site terminal are connected using the Internet or the like, there is no need to construct a dedicated network. Therefore, personal computers for the expert terminal and the on-site terminal and a modem for connecting these to the Internet By simply preparing the above, the inspection support system for mechanical equipment according to the present invention can be constructed, and the system can be easily introduced into various sites.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the inspection support system for mechanical equipment according to the present embodiment includes an expert terminal 10 installed at the location of an inspection expert (preventive maintenance expert).
And a site terminal 20 installed at the site where the mechanical equipment 40 to be inspected is provided. The site terminal 20 and the expert terminal 10 are connected by a communication line 30.

The expert terminal 10 obtains the inspection support information required for the inspection of the mechanical equipment 40 by the input from the input unit 11 or the internal generation thereof, and the inspection support information obtaining function. It has an inspection support information transmission function of transmitting the inspection support information to the site terminal 20 and an inspection result providing function of storing the inspection result information transmitted from the site terminal 20 in the storage unit 12 and performing external output such as display output. ing.

The on-site terminal 20 has a function of providing inspection support information for storing the inspection support information transmitted from the expert terminal 10 in the storage unit 21 and outputting it externally such as a display output, and the mechanical equipment 4.
It has an inspection result information transmission function of receiving input of inspection result information on the inspection result of 0 and transmitting the inspection result information to the expert terminal 10. The communication line 30 is composed of a public line such as the Internet. The expert terminal 10 and the on-site terminal 20 are connected to a communication line 30 via modems 31 and 32 that perform communication using analog signals.

In this embodiment, the expert terminal 1
0 has a function of acquiring and transmitting examination schedule information as examination support information. Also, the expert terminal 10
Has a function of acquiring and transmitting inspection procedure information as inspection support information. Further, the expert terminal 10 has an automatic schedule function for calculating next inspection schedule information based on the inspection result information.

On the other hand, the site terminal 20 has a vibration waveform data acquisition function for acquiring vibration waveform data of mechanical equipment as inspection result information. In response, the expert terminal 1
0 compares the vibration waveform data with preset abnormality diagnosis threshold data, and executes frequency analysis processing of the vibration waveform data when an abnormality of the vibration waveform data is recognized from the comparison result. .

This will be described in more detail.
Is a CRT in addition to the input unit 11 and the storage unit 12 described above.
And the like, and a CPU 14 for controlling these units. Here, the input unit 11 is a keyboard, a mouse, and the like, and the storage unit 12 is configured by a recording medium such as a RAM and a hard disk. Similarly, the site terminal 20 includes a storage unit 21, an input unit 22, a display unit 23, and a CPU 24. The above-described functions of the expert terminal 10 and the site terminal 20 correspond to each CPU 1
4 and 24.

The data shown in FIG. 2 is stored in the storage unit 12 of the professional terminal 10. In FIG. 2, the storage unit 1
2 is an inspection schedule table 121 storing the next inspection execution date (inspection schedule information), and an inspection result table 12 storing the previous inspection result (inspection result information).
2 and an inspection cycle table 123 storing a preset inspection cycle. The storage unit 12 stores the inspection procedure table 1 storing the inspection procedure (inspection procedure information).
24 and measurement data 125 received from the site terminal 20 as the inspection result of the mechanical equipment.

Further, the storage unit 12 includes an inspection schedule program 126 for realizing the above-described automatic schedule function of the inspection schedule, and a frequency analysis program 127 for analyzing the frequency of the vibration waveform data in the measurement data 125 and specifying an abnormal part. , Inspection schedule table 121, inspection result table 122, inspection cycle table 1
While transmitting inspection support information such as 23 to the site terminal,
A communication program 128 for receiving inspection result information from the site terminal 20 is stored. The inspection schedule program 126, the frequency analysis program 127, and the communication program 128 are executed by the CPU 14.

As shown in FIG. 3, the inspection cycle table 123 includes one or a plurality of inspection target devices (A device, I device,...).
・ ・) And the inspection part (B part, C part,
D part,...) And inspection contents (E inspection,
..) And the inspection cycle (one month, three months,...) For each inspection content at each inspection site. Note that “ID” in FIG. 3 is an identification ID of each record constituting the inspection cycle table.

As shown in FIG. 4, the inspection result table 122 stores, for each ID shown in FIG. 3, the date of the latest recent inspection and the result of repair or part replacement (a
..) And comments on the inspection (items to be reflected in the next inspection). As shown in FIG. 5, the inspection schedule table 121 stores the next scheduled inspection execution date for each ID shown in FIG.

The inspection procedure table 124 stores the IDs shown in FIG.
This is a table (not shown) in which text data describing the inspection procedure is registered for each. Here, the inspection cycle table 123 in FIG. 3, the inspection result table 122 in FIG.
The inspection schedule table 121 and the inspection procedure table are managed on the relational database using the ID as a key.

On the other hand, the storage unit 21 of the site terminal 20 shown in FIG.
As shown in FIG. 6, the inspection schedule table 211 and the inspection procedure table 2
12 is stored. The storage unit 21 stores the measurement data 213 received from the measurement device 50 attached to the inspection target 40.
And an inspection result input table 214 for registering inspection results input from the input unit 22.

The storage unit 21 includes a measurement data collection program 215 for reading the measurement data 213 sampled by the measuring device 50 into the storage unit 21;
3 and the information of the test result input table 214 to the expert terminal 10, and a communication program 216 for receiving information of the test schedule table 211 and the test procedure table 212 from the expert terminal 10.

Next, the operation of the present embodiment will be described with reference to FIGS. FIG. 7 shows the CPU 1 of the professional terminal 10.
4 is a flowchart of an inspection schedule program executed by the fourth embodiment. The inspection schedule program is CDR
The data may be read from a computer-readable medium such as an OM or a floppy disk. The preventive maintenance specialist operates the input unit 11 of the expert terminal 10 to check the inspection schedule program 126 stored in the storage unit 12.
Start When the program is started, the CPU 14
First, the inspection result table 122 is read from the storage unit 12 (S1), and then the inspection cycle table 123 is read (S2).

Thereafter, the inspection result table 1 shown in FIG.
The inspection cycle data of the inspection cycle table 123 shown in FIG. 3 is added to the data of the 22nd implementation day to make the next implementation date. At this time, in the inspection result table 122,
For a record having a record of repair or part replacement, a period set in advance according to the content of the repair or part replacement is further added to be a next scheduled inspection execution date (S3, FIG. 5). For example, in FIG. 4, two months are added for repair a, and six months are added for replacement b (FIG. 5).

The next scheduled inspection execution date calculated in this way is updated in the inspection schedule table 121 (S4). As a result, an automatic schedule function is realized. The CPU 14 displays the updated contents of the inspection schedule table 121 on the display unit 13. The preventive maintenance specialist checks the display or a printout of the display, and operates the input unit 11 to modify the scheduled date for the next scheduled inspection execution date if necessary, The inspection schedule table 121 is updated again (S5).

The preventive maintenance specialist uses the inspection result table 12
Display or printout of the comments stored in the input unit 1
1 can be requested from the CPU 1
Reference numeral 4 causes the comment of the requested record to be displayed on the display unit 13 or output to a printer or the like. Incidentally, the preventive maintenance specialist may reflect the content of the comment in the correction of the inspection schedule or the input of the next inspection procedure. Further, the preventive maintenance specialist can operate the input unit 11 to request an update of the inspection procedure table 124 in the storage unit 12. Upon receiving this request, the CPU 14 accepts a text input of the inspection procedure corresponding to the specified record, and updates this to a corresponding record in the inspection procedure table 124.
With the inspection procedure information, it is also possible to instruct parameter setting of a measuring device used for the inspection. With the above processing, the inspection support information acquisition function is realized.

On the other hand, the person in charge of the site activates the communication program 216 in the storage unit 21 from the input unit 22 of the site terminal 20, and further inputs a download request from the input unit 22. Upon receiving this request, the CPU 24 connects to the expert terminal 10 via the public line 30 and requests transmission of the inspection schedule table 121 and the inspection procedure table 124 stored in the storage unit 12.

In response to this request, the CPU of the professional terminal 10
14 starts the communication program 128 and transmits the inspection schedule table 121 and the inspection procedure table 124 to the site terminal 20 (inspection support information transmission function). The communication program 128 can be activated by a preventive maintenance expert operating the expert terminal 10. The above-described inspection support information can be transmitted from the expert terminal 10 to each site terminal 20. Is also possible.

The CPU 24 of the site terminal 20 stores the received inspection schedule table and inspection procedure table in the storage unit 21 of the terminal itself. Subsequently, the person in charge at the site activates the table browsing update program 217 from the input unit 22. FIG. 8 is a flowchart of the table browsing update program. The table browsing update program may be read from an external computer-readable medium. When the table browsing update program is started, the CPU 24 displays an initial screen on the display unit 23 (S11), and accepts an input of a date of an inspection execution date (S11).
12).

When the date is input from the input unit 22, the CP
U24 extracts, from the inspection schedule table 211, a record whose date is the scheduled inspection execution date,
The inspection device, the inspection site, and the inspection content corresponding to the ID of the record are displayed in a list on the display unit 23 (S13). Here, information on the inspection device, the inspection site, and the inspection content corresponding to the ID is stored in the storage unit 21 in advance (not shown).
Further, the CPU 24 receives a selection input of the record being displayed from the input unit 22 (S14), reads out the inspection procedure information corresponding to the selected record from the inspection procedure table 212, and displays it on the display unit 23 (S15). .

Thereafter, the CPU 24 monitors the input from the input section 22 and, if there is an input returning to the date input screen, S1.
Returning to step 2 (S16), when another record is selected from the displayed records, the inspection procedure information corresponding to the newly selected record is read from the inspection procedure table 212 and displayed on the display unit 23. If there is an input for terminating the program, the table browsing update program is terminated (S17). The inspection information providing function is realized by these processes. In this embodiment, when the person in charge inputs an arbitrary date, the record of the inspection schedule corresponding to the date is displayed, but the scheduled date is included in a period from today's date to several days later. All of the inspection schedules may be automatically displayed on the display unit 23.

The person in charge at the site inspects the inspection target 40 while referring to the display on the site terminal 20 or the printed output thereof. For example, when a vibration meter is used as the measuring device 50 and the vibration waveform of the inspection object 40 is sampled, the vibration waveform data is collected in the internal memory of the vibration meter, and the vibration meter is connected to the site terminal 20. The measurement data collection program 215 is started from the input unit 22 of the above, and the data stored in the internal memory of the vibrometer is read into the storage unit 21 (vibration waveform data acquisition function).

The site clerk who has completed the inspection activates the table browsing update program 217 from the input unit 22, and
Select the test result input menu. Then, the input unit 22
From the ID of FIG. 3 corresponding to the inspection as the inspection result information
, The date of execution of the inspection, the result of repair or replacement of parts accompanying the inspection, and a comment to be reflected in the next inspection. The CPU 24 updates these input items in the inspection result input table for each ID.

Thereafter, the person in charge at the site activates the communication program 216 from the input unit 22 and requests upload. Upon receiving this request, the CPU 24 connects to the expert terminal 10 and stores the measurement data 213 stored in the storage unit 21 of the own device.
And the contents of the inspection result input table 214 into the expert terminal 1
0 (inspection result information transmission function).
The CPU 14 of the expert terminal 10 executes the communication program 128
Is started, the measurement data from the site terminal 20 is received and stored in the storage unit 12, and the contents of the inspection result input table 214 from the site terminal 20 are updated to the inspection result table 122 in the storage unit 12.

By operating the input unit 11, the preventive maintenance specialist can obtain the measurement data 125 and the inspection result table 12.
2 can be requested to be displayed on the display unit 13 or to be printed out by a printer. CP that received this request
U14 indicates the measurement data 125 and the inspection result table 122
Is displayed on the display unit 13 or printed out by a printer (inspection result providing function).

Thereafter, in the expert terminal 10, the execution of the already described inspection schedule program and the like are repeated as appropriate. Further, the preventive maintenance specialist identifies the abnormal part of the inspection target 40 by activating the frequency analysis program 127 of the expert terminal 10. When the frequency analysis program 127 is started, the CPU 14 reads the measurement data 12
The vibration waveform data acquired as No. 5 is compared with preset abnormality diagnosis threshold data, and when an abnormality of the vibration waveform data is recognized from the comparison result, the frequency analysis processing of the vibration waveform data is executed, and the result is obtained. It is displayed on the display unit 13. Preventive maintenance specialists will consider this result in the next inspection schedule.

According to the above-described embodiment, the following effects can be obtained. That is, since the inspection support information, the inspection result information, and the like are exchanged between the expert terminal 10 and the site terminal 20 via the communication line 30, the machine equipment 40
Experts with expertise in prevention or maintenance of abnormalities can provide their expertise to the site without having to visit the site, reducing the cost of preventive / maintenance work and speeding up the preventive / maintenance work. Implementation can be achieved.

Further, since the inspection support information includes the inspection schedule table 121 which is the inspection schedule information, even if the expert does not go to the site, the person in charge of the site based on the inspection schedule given by the expert. Can perform preventive maintenance work at an appropriate timing.

Further, since the inspection support information is configured to include the inspection procedure table 124 which is the inspection procedure information, the inspection of the mechanical equipment 40 according to the procedure based on the inspection procedure information at the site without the presence of an expert. Can be performed, and the person in charge of the site can perform the inspection by an appropriate procedure without requiring specialized knowledge. Since the information of such an inspection procedure table 124 can be changed at the expert terminal 10, an appropriate inspection procedure based on the judgment of the expert can be obtained on site in real time, and the prevention of mechanical equipment can be prevented. , Maintenance can be performed more reliably.

The expert terminal 10 has an automatic schedule function for calculating inspection schedule information based on the measurement data 213 transmitted from the site terminal 20 and the inspection result information including the inspection result input table 214. Therefore, it is possible to automatically determine the date of the next inspection according to the date of the previous inspection or the fact of repair or replacement of parts in the previous inspection, etc., and reduce the work of preventive maintenance specialists on schedule work. Can be.

Further, the on-site terminal 20 has a vibration waveform data acquisition function for acquiring vibration waveform data of the mechanical equipment 40 as inspection result information, and the expert terminal 10 transmits the vibration waveform data to the preset abnormality diagnosis threshold data. When the abnormality is found in the vibration waveform data from the comparison result, the frequency analysis processing of the vibration waveform data is performed. Therefore, when no abnormality is found in the vibration waveform data, the frequency analysis processing can be omitted. In addition, unnecessary calculation load can be omitted.

Since the Internet, which is a public line, is used as the communication line 30, the expert terminal 1
0 and the on-site terminal 20 do not need to be connected by a dedicated network.
By simply preparing the modems 31 and 32, an inspection support system for the mechanical equipment 40 can be constructed, and the system can be easily introduced into various sites.

It should be noted that the present invention is not limited to the above-described embodiment, but includes the following modifications. That is, in the embodiment, the expert terminal 10 and the on-site terminal 20 are exclusively input from the on-site terminal 20.
The communication of the test support information and the test result information is performed during this period. However, the present invention is not limited to this, and the communication of the information may be performed based on the input from the expert terminal 10.

In the above embodiment, the Internet is used as the communication line 30, but the present invention is not limited to this.
The communication line may be configured by a dedicated network based on a specific protocol using a public line. further,
In the above-described embodiment, the vibration waveform data is adopted as the inspection result information. However, the invention is not limited to this, and various data can be adopted as the inspection result information as long as the characteristic values are necessary for the inspection of the mechanical equipment. . In addition, the specific structure, shape, and the like of the present invention may be other structures and the like as long as the object of the present invention can be achieved.

[0050]

According to the inspection support system for mechanical equipment of the present invention as described above, inspection support information, inspection result information, and the like are exchanged between a specialist terminal and a site terminal via a communication line. Even if experts with expertise in prevention or maintenance of mechanical equipment abnormalities do not visit the site, they can provide their expertise to the site,
Costs for maintenance work can be reduced and preventive and maintenance work can be performed quickly.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.

FIG. 2 is a data structure diagram in which a storage unit in the expert terminal of FIG. 1 is partially omitted.

FIG. 3 is a data structure diagram in which a part of the inspection cycle table in FIG. 2 is omitted.

FIG. 4 is a data structure diagram in which a part of the inspection result table in FIG. 2 is omitted.

FIG. 5 is a data structure diagram in which a part of the inspection schedule table in FIG. 2 is omitted.

FIG. 6 is a data structure diagram in which a storage unit in the site terminal of FIG. 1 is partially omitted.

FIG. 7 is a flowchart of the inspection schedule program shown in FIG.

FIG. 8 is a flowchart of a table browsing update program shown in FIG. 6;

[Explanation of symbols]

 Reference Signs List 10 expert terminal 11 input unit 12 storage unit 13 display unit 14 CPU 20 field terminal 21 storage unit 22 input unit 23 display unit 24 CPU 30 public line (communication line) 40 test target 50 measuring device

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2G024 AD03 AD04 BA11 CA13 EA01 EA02 FA06 FA11 2G064 AB07 DD01

Claims (6)

[Claims] An expert terminal installed at the location of an inspection expert and a site terminal installed at a site equipped with a machine to be inspected are provided. A communication line is connected between the site terminal and the expert terminal. The expert terminal, the inspection support information necessary for the inspection of the mechanical equipment, the inspection support information acquisition function to obtain by input from the input unit or by generating in the inside, the inspection support information the site terminal An inspection support information transmission function of transmitting the inspection result information transmitted from the site terminal to a storage unit, and a test result providing function of performing an external output such as a display output by storing the inspection result information in a storage unit. The inspection support information transmitted from the terminal is stored in a storage unit, and an inspection support information providing function of performing an external output such as a display output, and an input of inspection result information regarding an inspection result of the mechanical equipment are received. Test support system of mechanical equipment which is characterized by comprising a inspection result information transmitting function of transmitting the inspection result information to the expert terminal. 2. The machine equipment inspection support system according to claim 1, wherein said inspection support information is configured to include inspection schedule information indicating an inspection schedule of said machine equipment. Inspection support system. 3. The machine equipment inspection support system according to claim 2, wherein the inspection support information includes inspection procedure information representing an inspection procedure of the machine equipment. Inspection support system. 4. The inspection support system for mechanical equipment according to claim 2, wherein the expert terminal has an automatic schedule function for calculating the inspection schedule information based on the inspection result information. An inspection support system for machinery and equipment. 5. The inspection support system for mechanical equipment according to claim 1, wherein said site terminal acquires vibration waveform data of said mechanical equipment as said inspection result information. With the function, the expert terminal compares the vibration waveform data with preset abnormality diagnosis threshold data, and when an abnormality of the vibration waveform data is recognized from the comparison result, the frequency analysis of the vibration waveform data is performed. An inspection support system for mechanical equipment, which performs processing. 6. The inspection support system for mechanical equipment according to claim 1, wherein a public line is used as said communication line.