CN113222399A - Engineering equipment operation guarantee comprehensive efficiency evaluation method - Google Patents
Engineering equipment operation guarantee comprehensive efficiency evaluation method Download PDFInfo
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- CN113222399A CN113222399A CN202110499801.7A CN202110499801A CN113222399A CN 113222399 A CN113222399 A CN 113222399A CN 202110499801 A CN202110499801 A CN 202110499801A CN 113222399 A CN113222399 A CN 113222399A
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Abstract
The invention discloses a comprehensive efficiency evaluation method for engineering equipment operation guarantee, which comprises the following operation steps: s1: the method comprises the steps that a plurality of engineering operation devices with different types and models are randomly extracted, comprehensive efficiency evaluation is carried out on the engineering devices of different types, the engineering devices are mainly divided into armored vehicles, scouting vehicles, transport vehicles, logistics support vehicles and the like, and the comprehensive efficiency evaluation of the engineering devices is mainly divided into operation distance detection evaluation, operation speed detection evaluation and compression resistance detection evaluation. According to the method for evaluating the comprehensive efficiency of the engineering equipment operation guarantee, the engineering operation equipment is evaluated in aspects of speed, distance, compression resistance, control, environmental requirement coping, capacity and the like, various performance indexes of military engineering operation equipment are collected after being detected, tables are sorted, and the comprehensive performance of the military engineering operation equipment is evaluated by combining the various indexes, so that data can be obtained conveniently and better, the accuracy is higher, and better use prospects are brought.
Description
Technical Field
The invention relates to the field of engineering equipment operation evaluation, in particular to an engineering equipment operation guarantee comprehensive efficiency evaluation method.
Background
The method for evaluating the comprehensive efficiency of the engineering equipment operation guarantee is a supporting method for comprehensively evaluating the engineering equipment operation guarantee, the engineering equipment operation guarantee is more and more important to use nowadays, the actual force can be shown to a great extent, the safety is guaranteed, a great deterrent effect is achieved, the method for evaluating the engineering equipment operation guarantee is more comprehensive, the guarantee evaluation of the equipment is imperative in order to clearly know the task completion condition of an equipment guarantee system, and the manufacturing process requirements of people on the method for evaluating the comprehensive efficiency of the engineering equipment operation guarantee are higher and higher along with the continuous development of science and technology.
The conventional method for evaluating the comprehensive efficiency of the operation guarantee of the engineering equipment has certain disadvantages in use, the evaluation of the engineering equipment is single, the comprehensive evaluation effect is poor, the evaluation accuracy cannot be greatly improved, the conventional evaluation method is difficult to adapt to the modern wartime requirement, is not beneficial to the use of people, and brings certain adverse effects to the use process of people.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides an engineering equipment operation guarantee comprehensive efficiency evaluation method, which is used for evaluating the engineering operation equipment in aspects of speed, distance, compression resistance, control, environmental requirement coping, capacity and the like, summarizing and sorting tables after detecting various performance indexes of the engineering operation equipment, and evaluating the comprehensive performance of the engineering operation equipment by combining the various indexes, so that data can be conveniently and better obtained, the accuracy is higher, and the problems in the background art can be effectively solved.
In order to achieve the purpose, the invention adopts the technical scheme that: a comprehensive efficiency evaluation method for engineering equipment operation guarantee comprises the following operation steps:
s1: randomly extracting a plurality of engineering operation equipment with different types and models, and carrying out comprehensive efficiency evaluation on the engineering equipment of different types, wherein the engineering equipment is mainly divided into an armored vehicle, a scout vehicle, a transport vehicle, a logistics support vehicle and the like, and the comprehensive efficiency evaluation of the engineering equipment is mainly divided into several aspects of operation distance detection evaluation, operation speed detection evaluation, compression resistance detection evaluation, capacity storage detection evaluation, environment operation detection evaluation, control system detection evaluation and the like;
s2: firstly, detecting the working distance and the working speed of engineering operation equipment, adding the oil quantity storage of the engineering operation equipment to be the fullest, selecting different road sections to test the engineering operation equipment, checking the driving distance of the engineering operation equipment after the oil quantity in the different road sections is consumed and the fastest speed of the engineering operation equipment in the different road sections, and obtaining distance and speed indexes;
s3: secondly, detecting the compression resistance of the engineering operation equipment, stopping the engineering operation equipment to a specified striking point, striking the engineering operation equipment with certain force at different distances and speeds, checking the damage degree of the engineering operation equipment under different stress conditions, and obtaining the compression resistance index of the engineering operation equipment;
s4: then, detecting the capacity storage of the engineering operation equipment, preparing different types of engineering operation transport objects, respectively transporting the engineering operation transport objects, checking the transport volume of the engineering operation objects by the different types of engineering operation equipment, and obtaining the capacity storage index of the engineering operation equipment;
s5: then, detecting the environmental operation conditions of the engineering operation equipment, respectively detecting different engineering operation equipment in different environments, checking the distance and the speed of the engineering operation equipment in different environments, knowing the striking strength of the engineering operation equipment, and obtaining operation indexes of the engineering operation equipment corresponding to different environments;
s6: finally, detecting a control system of the engineering operation equipment, remotely controlling the engineering operation equipment on different occasions, checking the control sensitivity and accuracy, determining a hitting target, checking the control degree and obtaining the performance index of the engineering operation equipment control system;
s7: after detecting each performance index of the engineering operation equipment, summarizing, sorting the table, and evaluating the comprehensive performance of the engineering operation equipment by combining each index, so that the data can be obtained conveniently and better, and the accuracy is higher.
As a preferable technical solution, in the step S1, the work equipment is evaluated in terms of speed, distance, pressure resistance, control, environmental requirement, capacity, and the like, and the evaluated work equipment is equipped with an armored car, a scout car, a transport car, a logistics support vehicle, and the like.
As a preferable technical solution, in the step S2, the oil storage capacity of the transport vehicle in the engineering operation equipment is 120 liters, and the driving distance in the full oil state is 1000km to 1200 km.
As a preferable technical solution, the maximum speed of the transport vehicle in the engineering operation equipment in the step S2 is 120 km/h.
As a preferable technical solution, the striking force for the engineering equipment operation in the step S3 is 2000 newton to 7000 newton.
As a preferable technical solution, the engineering work transportation in the step S4 is mainly divided into three types, which are materials, personnel and machinery.
As a preferable technical solution, the environment in the step S5 may be a weather environment, which is divided into a sunny day, a rainy day, a snowy day, and the like, or an ecological environment, which is divided into a common area, a region with a serious sand storm, a region with a serious haze, and the like.
As a preferable technical solution, the control and detection of the engineering operation equipment in the step S6 mainly include wireless remote control, accuracy control, real-time system control, and the like.
Compared with the prior art, the invention provides an engineering equipment operation guarantee comprehensive efficiency evaluation method, which has the following beneficial effects: the method for evaluating the comprehensive efficiency of the engineering equipment operation guarantee comprises the steps of evaluating the engineering equipment to speed, distance, compression resistance, control, environmental requirement and capacity, collecting all performance indexes of the engineering equipment after detection, sorting tables, evaluating the comprehensive performance of the engineering equipment by combining all the indexes, conveniently and better obtaining data, having higher accuracy, detecting the operation distance and the operation speed of the engineering equipment, adding the oil quantity storage of the engineering equipment to the fullest, selecting different road sections to test the engineering equipment, checking the driving distance of the engineering equipment after the oil quantity consumption in different road sections and the fastest speed of the engineering equipment in different road sections to obtain the distance and speed indexes, detecting the compression resistance of the engineering equipment, stopping the engineering equipment to a designated striking point, striking the engineering equipment with a certain force at different distances and speeds, checking the damage degree of the engineering operation equipment under different stress conditions to obtain the compressive performance index of the engineering operation equipment, then detecting the capacity storage of the engineering operation equipment, preparing different types of engineering operation transport objects, respectively transporting the engineering operation transport objects, checking the transport quantity of the engineering operation objects of the different types of engineering operation equipment to obtain the capacity storage index of the engineering operation equipment, then detecting the environment operation conditions of the engineering operation equipment, respectively detecting the different engineering operation equipment under different environments, checking the transmitting distance and the speed of the engineering operation equipment in different environments, knowing the striking force of the engineering operation equipment, obtaining the operation indexes of the engineering operation equipment to the different environments, and finally detecting a control system of the engineering operation equipment, the engineering operation equipment is remotely controlled in different occasions, the control sensitivity and the control accuracy are checked, the hitting target is determined, the control degree is checked, and the performance index of the engineering operation equipment control system is obtained.
Drawings
The invention is further explained below with reference to the drawings and examples.
Fig. 1 is a schematic view of an overall structure of the method for evaluating the comprehensive efficiency of the engineering equipment operation guarantee according to the present invention.
Detailed Description
As shown in fig. 1, a method for evaluating the comprehensive performance of the engineering equipment operation guarantee includes the following steps:
s1: randomly extracting a plurality of engineering operation equipment with different types and models, and carrying out comprehensive efficiency evaluation on the engineering equipment with different types, wherein the engineering equipment is mainly divided into an armored vehicle, a scout vehicle, a transport vehicle, a logistics support vehicle and the like, and the comprehensive efficiency evaluation of the engineering equipment is mainly divided into several aspects of operation distance detection evaluation, operation speed detection evaluation, compression resistance detection evaluation, capacity storage detection evaluation, environment operation detection evaluation, control system detection evaluation and the like;
s2: firstly, detecting the working distance and the working speed of engineering operation equipment, adding the oil quantity storage of the engineering operation equipment to be the fullest, selecting different road sections to test the engineering operation equipment, checking the driving distance of the engineering operation equipment after the oil quantity in the different road sections is consumed and the fastest speed of the engineering operation equipment in the different road sections, and obtaining distance and speed indexes;
s3: secondly, detecting the compression resistance of the engineering operation equipment, stopping the engineering operation equipment to a specified striking point, striking the engineering operation equipment with certain force at different distances and speeds, checking the damage degree of the engineering operation equipment under different stress conditions, and obtaining the compression resistance index of the engineering operation equipment;
s4: then, detecting the capacity storage of the engineering operation equipment, preparing different types of engineering operation transport objects, respectively transporting the engineering operation transport objects, checking the transport volume of the engineering operation objects by the different types of engineering operation equipment, and obtaining the capacity storage index of the engineering operation equipment;
s5: then, detecting the environmental operation conditions of the engineering operation equipment, respectively detecting different engineering operation equipment in different environments, checking the distance and the speed of the engineering operation equipment in different environments, knowing the striking strength of the engineering operation equipment, and obtaining operation indexes of the engineering operation equipment corresponding to different environments;
s6: finally, detecting a control system of the engineering operation equipment, remotely controlling the engineering operation equipment on different occasions, checking the control sensitivity and accuracy, determining a hitting target, checking the control degree and obtaining the performance index of the engineering operation equipment control system;
s7: after detecting each performance index of the engineering operation equipment, summarizing, sorting the table, and evaluating the comprehensive performance of the engineering operation equipment by combining each index, so that the data can be obtained conveniently and better, and the accuracy is higher.
Further, the work equipment is evaluated in S1 for speed, distance, pressure resistance, control, environmental requirements, capacity, etc., and the evaluated work equipment is equipped with armored cars, scouts, transportation cars, logistics vehicles, etc.
Further, the oil storage amount of the transport vehicle in the engineering work equipment in the step S2 is 120 liters, and the driving distance in the full oil state is 1000km to 1200 km.
Further, the maximum speed of the transport vehicle in the working equipment of the project in the step S2 is 120 km/h.
Further, the striking force of the engineering equipment operation in the step S3 is 2000-7000N.
Further, the engineering operation transportation in the step S4 is mainly divided into three types, namely, material, personnel and machinery.
Further, the environment in the step S5 may be a weather environment, which is divided into a sunny day, a rainy day, a snowy day, and the like, or an ecological environment, which is divided into a general area, a region where a sand storm is seriously removed, a region where haze is seriously removed, and the like.
Further, the control and detection of the engineering operation equipment in the step S6 are mainly wireless remote control, accuracy control, real-time system control, and the like.
The working principle is as follows: the method comprises the steps of randomly extracting a plurality of engineering operation equipment with different types and models, carrying out comprehensive efficiency evaluation on the engineering equipment with different types, wherein the engineering equipment is mainly divided into an armored vehicle, a scout vehicle, a transport vehicle, a logistics support vehicle and the like, the comprehensive efficiency evaluation of the engineering equipment is mainly divided into operation distance detection evaluation, operation speed detection evaluation, compression resistance detection evaluation, capacity storage detection evaluation, environment operation detection evaluation, control system detection evaluation and the like, firstly, detecting the operation distance and the operation speed of the engineering operation equipment, adding the oil quantity storage of the engineering operation equipment to the fullest, selecting different road sections to test the engineering operation equipment, checking the driving distance of the engineering operation equipment after the oil quantity is consumed in different road sections and the fastest speed of the engineering operation equipment in different road sections to obtain distance and speed indexes, secondly, detecting the compression resistance of the engineering operation equipment, stopping the engineering operation equipment to a designated striking point, striking the engineering operation equipment with a certain force at different distances and speeds, checking the damage degree of the engineering operation equipment under different stress conditions to obtain a compression resistance index of the engineering operation equipment, then detecting the capacity storage of the engineering operation equipment, preparing different types of engineering operation transport objects, transporting the engineering operation transport objects respectively, checking the transport quantity of the engineering operation objects by the different types of engineering operation equipment to obtain a capacity storage index of the engineering operation equipment, then detecting the environment operation condition of the engineering operation equipment, detecting the different engineering operation equipment under different environments respectively, checking the transmitting distance and the speed of the engineering operation equipment in different environments to know the striking force, the method comprises the steps of obtaining operation indexes of the engineering operation equipment corresponding to different environments, finally, detecting a control system of the engineering operation equipment, remotely controlling the engineering operation equipment on different occasions, checking the control sensitivity and the control accuracy, determining a hitting target, checking the control degree to obtain performance indexes of the control system of the engineering operation equipment, collecting and arranging tables after detecting all the performance indexes of the engineering operation equipment, and carrying out comprehensive performance evaluation on the tables by combining all the indexes, so that data can be obtained conveniently and better, and the accuracy is higher.
The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.
Claims (8)
1. A comprehensive efficiency evaluation method for engineering equipment operation guarantee is characterized by comprising the following steps: the method comprises the following operation steps:
s1: randomly extracting a plurality of engineering operation equipment with different types and models, and carrying out comprehensive efficiency evaluation on the engineering equipment of different types, wherein the engineering equipment is mainly divided into an armored vehicle, a scout vehicle, a transport vehicle and a logistics support vehicle, and the comprehensive efficiency evaluation of the engineering equipment is mainly divided into several aspects of operation distance detection evaluation, operation speed detection evaluation, compression resistance detection evaluation, capacity storage detection evaluation, environment operation detection evaluation and control system detection evaluation;
s2: firstly, detecting the working distance and the working speed of engineering operation equipment, adding the oil quantity storage of the engineering operation equipment to be the fullest, selecting different road sections to test the engineering operation equipment, checking the driving distance of the engineering operation equipment after the oil quantity in the different road sections is consumed and the fastest speed of the engineering operation equipment in the different road sections, and obtaining distance and speed indexes;
s3: secondly, detecting the compression resistance of the engineering operation equipment, stopping the engineering operation equipment to a specified striking point, striking the engineering operation equipment with certain force at different distances and speeds, checking the damage degree of the engineering operation equipment under different stress conditions, and obtaining the compression resistance index of the engineering operation equipment;
s4: then, detecting the capacity storage of the engineering operation equipment, preparing different types of engineering operation transport objects, respectively transporting the engineering operation transport objects, checking the transport volume of the engineering operation objects by the different types of engineering operation equipment, and obtaining the capacity storage index of the engineering operation equipment;
s5: then, detecting the environmental operation conditions of the engineering operation equipment, respectively detecting different engineering operation equipment in different environments, checking the distance and the speed of the engineering operation equipment in different environments, knowing the striking strength of the engineering operation equipment, and obtaining operation indexes of the engineering operation equipment corresponding to different environments;
s6: finally, detecting a control system of the engineering operation equipment, remotely controlling the engineering operation equipment on different occasions, checking the control sensitivity and accuracy, determining a hitting target, checking the control degree and obtaining the performance index of the engineering operation equipment control system;
s7: after detecting each performance index of the engineering operation equipment, summarizing, sorting the table, and evaluating the comprehensive performance of the engineering operation equipment by combining each index, so that the data can be obtained conveniently and better, and the accuracy is higher.
2. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: and in the step S1, the engineering operation equipment is evaluated in aspects of speed, distance, pressure resistance, control, environmental requirement handling and capacity, and the evaluated engineering is equipped with an armored vehicle, a scout vehicle, a transport vehicle and a logistics support vehicle.
3. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: and in the step S2, the oil storage capacity of the transport vehicle in the engineering operation equipment is 120 liters, and the running distance in the full oil state is 1000km-1200 km.
4. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: the maximum speed of the transport vehicle in the engineering operation equipment in the step S2 is 120 km/h.
5. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: and the striking force for engineering equipment operation in the step S3 is 2000-7000N.
6. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: the engineering operation transportation objects in the step S4 are mainly divided into three types, namely materials, personnel and machinery.
7. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: the environment in the step S5 may be a weather environment, which is divided into sunny days, rainy days, and snowy days, or an ecological environment, which is divided into a common area where sand storm and haze are severe.
8. The method for evaluating the comprehensive performance of the engineering equipment operation support according to claim 1, wherein the method comprises the following steps: and in the step S6, the control and detection of the engineering operation equipment are mainly wireless remote control, accuracy rate control and real-time system control.
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