CN114817866B - Electric drill power calculation method and system based on main shaft bias load field analysis - Google Patents

Abstract

The invention relates to the technical field of data processing, in particular to an electric drill power calculation method and system based on main shaft bias load field analysis, wherein the method comprises the following steps: based on the offset distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by personnel, the power of the electric drill is adjusted according to the using state of the electric drill through data processing. The method and the system are particularly suitable for a data processing method or data processing equipment with a specific function, particularly suitable for an electric drill power calculation method and system, and can adjust the power of an electric drill in time to avoid the damage of the electric drill; the method can also be applied to internet data services such as big data resource services, databases, cloud database services and the like, and cloud computing software and cloud fusion application operation support platform software.

Description

Electric drill power calculation method and system based on main shaft bias load field analysis

Technical Field

The invention relates to the field of data processing, in particular to an electric drill power calculation method and system based on spindle offset load field analysis.

Background

The user often discovers that the electric drill has a problem due to reasons such as long use or improper use after the temperature of the electric drill is too high or the electric drill does not work, and the power of the electric drill cannot be adjusted to avoid risks before the problem occurs, so that the service life of the electric drill is greatly shortened.

Disclosure of Invention

In order to solve the technical problems, the invention aims to provide an electric drill power calculation method and system based on spindle offset load field analysis, and the adopted technical scheme is as follows:

in a first aspect, an embodiment of the present invention provides a power calculation method for a power drill based on a spindle bias load field analysis, the method including the following specific steps:

acquiring the offset distance of an electric drill bit, the internal temperature of the electric drill, the abrasion loss of the electric drill bit and the force applied to the electric drill by personnel based on a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

calculating a loss index of the electric drill based on the offset distance sequence and the wear amount sequence;

calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

calculating the service life influence index of the electric drill based on the force application sequence and the aging degree index;

and adjusting the power of the electric drill according to the influence indexes of the service life of the electric drill.

Further, calculating a loss index of the electric drill based on the offset distance sequence and the wear loss sequence, specifically:

acquiring a variance of offset distances based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence;

carrying out positive correlation mapping on the range to obtain a range mapping value;

and the product of the variance and the range mapping value is a loss index of the electric drill.

Further, based on the internal temperature sequence and the loss index, calculating an aging degree index of the electric drill, specifically:

obtaining the difference value between each internal temperature in the internal temperature sequence and the room temperature at the corresponding moment to obtain a temperature difference value sequence;

acquiring the range of the temperature difference value based on the temperature difference value sequence;

and the product of the extreme difference of the temperature difference value and the loss index of the electric drill is the aging degree index of the electric drill.

Further, based on the force application sequence and the aging degree index, calculating a service life influence index of the electric drill, specifically:

acquiring a maximum value of the applied force based on the applied force sequence, and acquiring a component force of the maximum value of the applied force in a direction perpendicular to the working surface; calculating a ratio of the component force to the application force maximum;

and calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio.

Further, the service life influence index of the electric drill and the aging degree index of the electric drill are in an inverse correlation relationship; and the service life influence index of the electric drill is in an inverse correlation with the ratio.

In a second aspect, another embodiment of the present invention provides a power drill power calculation system based on in situ analysis of spindle bias load, specifically comprising:

the data acquisition module is used for acquiring the offset distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by personnel on the basis of a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

the loss index calculation module is used for calculating the loss index of the electric drill based on the offset distance sequence and the abrasion loss sequence;

the aging degree index calculation module is used for calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

the electric drill service life influence index calculation module is used for calculating an electric drill service life influence index based on the application force sequence and the aging degree index;

and the power adjusting module is used for adjusting the power of the electric drill according to the influence indexes of the service life of the electric drill.

Further, the loss index calculation module includes:

a wear amount range acquisition unit configured to acquire a variance of offset distances based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence;

the range mapping unit is used for carrying out positive correlation mapping on the range to obtain a range mapping value;

and the first calculating unit is used for calculating the product of the variance and the range mapping value to obtain the loss index of the electric drill.

Further, the aging degree index calculation module comprises:

a difference sequence obtaining unit, configured to obtain a difference between each internal temperature in the internal temperature sequence and a room temperature at a corresponding time, so as to obtain a temperature difference sequence;

the temperature difference range acquiring unit is used for acquiring the range of the temperature difference based on the temperature difference sequence;

and the second calculating unit is used for calculating the product of the extreme difference of the temperature difference value and the loss index of the electric drill to obtain the aging degree index of the electric drill.

Further, the electric drill service life influence index calculation module comprises:

the ratio acquisition unit is used for acquiring a maximum value of the applied force based on the applied force sequence and acquiring a component force of the maximum value of the applied force in a direction vertical to the working surface; calculating a ratio of the force component to the force application maximum;

and the third calculating unit is used for calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio.

Further, the service life influence index of the electric drill and the aging degree index of the electric drill are in an inverse correlation relationship; and the service life influence index of the electric drill is in an inverse correlation with the ratio.

The embodiment of the invention at least has the following beneficial effects: the invention particularly relates to an electric drill power calculation method and system based on main shaft offset load field analysis, and particularly relates to an electric drill power calculation method and system based on the offset distance of an electric drill bit, the internal temperature of an electric drill, the abrasion loss of the electric drill bit and the force applied to the electric drill by personnel. The method and the system are particularly suitable for a data processing method or data processing equipment with a specific function, particularly suitable for an electric drill power calculation method and system, and can adjust the power of an electric drill in time to avoid the damage of the electric drill; the method can also be applied to internet data services such as big data resource services, databases, cloud database services and the like, and cloud computing software and cloud fusion application operation support platform software.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions and advantages of the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a flowchart illustrating steps of a power drill power calculation method based on spindle bias load field analysis according to an embodiment of the present invention.

Fig. 2 is a block diagram of a power calculation system for a power drill based on in-situ analysis of a spindle offset load according to an embodiment of the present invention.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description will be given of a power calculation method and system for a drill based on a spindle bias load field analysis according to the present invention, with reference to the accompanying drawings and preferred embodiments, and specific embodiments, structures, features and effects thereof. In the following description, different "one embodiment" or "another embodiment" refers to not necessarily the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

The following specifically describes a specific scheme of the electric drill power calculation method and system based on the spindle bias load field analysis, which is provided by the invention, with reference to the accompanying drawings.

Referring to fig. 1, a flow chart illustrating steps of a method for calculating power of a power drill based on a spindle bias load field analysis according to an embodiment of the present invention is shown, wherein the method comprises the following steps:

acquiring the offset distance of an electric drill bit, the internal temperature of the electric drill, the abrasion loss of the electric drill bit and the force applied to the electric drill by personnel based on a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

calculating a loss index of the electric drill based on the offset distance sequence and the wear amount sequence;

calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

calculating a service life influence index of the electric drill based on the application force sequence and the aging degree index;

and adjusting the power of the electric drill according to the influence indexes of the service life of the electric drill.

The above steps are specifically described below:

step S1, acquiring the offset distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by personnel based on a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is a force applied by a person to the drill.

The electric drill can cause the abrasion of the internal bearing after being used for a long time, the bearing abrasion can lead the drill bit to shake when in use, and then the rotation precision of the drill bit is reduced, and the normal working and use of the electric drill can be influenced along with the reduction of the rotation precision. Therefore, the deflectable distance of the drill bit needs to be collected, and it needs to be explained that any position on the drill bit can be selected to obtain the deflectable distance of the drill bit, after the position is selected, the deflectable distance of the drill bit is obtained subsequently based on the position, the position can be a middle position of the drill bit or a drill bit position, and the like, and the deflectable distance of the drill bit is a maximum shaking distance when the drill bit is shaken; preferably, the embodiment obtains the offsetable distance of the drill bit based on the position of the drill bit in contact with the work object. The practitioner may obtain the offsetable distance of the drill bit with the aid of a straightedge or other distance measuring instrument.

Along with the increase of the operation time of the electric drill, the internal temperature of the electric drill continuously rises, the aging of parts inside the electric drill is aggravated, and the service life of the electric drill is influenced by the aging of the parts. Therefore, the internal temperature of the electric drill needs to be collected. The practitioner may use a temperature sensor to obtain the temperature inside the drill.

When the electric drill normally works, under the action of the internal lubricating oil, the abrasion degree of the bearing is slight, but along with the increase of the service life, a large amount of dust is accumulated inside the electric drill, and the lubricating oil is absorbed by the dust, so that the abrasion degree between the bearings is increased during the operation. Therefore, the amount of drill bit wear of the drill is also an important data. The implementer may obtain the drill bit wear amount of the electric drill according to the diameter or radius change of the drill bit in contact with the operation object, specifically, the difference between the currently obtained drill bit diameter and the previously obtained drill bit diameter is the drill bit wear amount, or the difference between the currently obtained drill bit radius and the previously obtained drill bit radius is the drill bit wear amount.

Because the strength and the direction of the electric drill used by a user can directly influence the service life of the drill bit, the force applied to the electric drill by a user is required to be collected. The force applied by the person to the electric drill is a vector and has a magnitude and a direction. In the embodiment, an angle measuring instrument and a pressure measuring instrument are arranged on a handle of the electric drill, wherein the angle measuring instrument is used for measuring an angle between the electric drill and an operation surface, and the pressure measuring instrument is used for measuring the force applied by a person to the electric drill. It should be noted that each element in the acquired force application sequence is a doublet, and the doublet includes the magnitude and direction of the applied force, and the direction is the angle between the drill and the working face.

Therefore, during the operation of the electric drill, the deflectable distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by a person are obtained based on the preset time interval, and a deflection distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applied sequence are obtained. Preferably, in the embodiment, the working time is one hour, the preset time interval is ten minutes, and the offset distance sequence, the internal temperature sequence, the wear amount sequence and the force application sequence are acquired.

And step S2, calculating a loss index of the electric drill based on the offset distance sequence and the wear amount sequence.

Calculating a loss index of the electric drill based on the offset distance sequence and the abrasion loss sequence, specifically: acquiring a variance of the offset distance based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence; carrying out positive correlation mapping on the range to obtain a range mapping value; and the product of the variance and the range mapping value is a loss index of the electric drill. The larger the variance of the offset distance, the larger the range mapping value, indicating the more severe the drill loss.

In one embodiment, the range is mapped positively by using a logarithmic function to obtain a range mapping value. Preferably, the logarithmic function is an ln function.

And step S3, calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index.

Based on the internal temperature sequence and the loss index, calculating an aging degree index of the electric drill, specifically: obtaining the difference value between each internal temperature in the internal temperature sequence and the room temperature at the corresponding moment to obtain a temperature difference value sequence; acquiring the range of the temperature difference value based on the temperature difference value sequence; and the product of the extreme difference of the temperature difference value and the loss index of the electric drill is the aging degree index of the electric drill. The larger the aging degree index value of the electric drill is, the more serious the electric drill is aged.

Due to different seasons, the temperature rise degree is different in summer and winter, and the temperature rise caused by the operation of the electric drill is obtained by subtracting the room temperature from the internal temperature of the electric drill acquired by the temperature sensor.

And step S4, calculating the influence index of the service life of the electric drill based on the application force sequence and the aging degree index.

Based on the force application sequence and the aging degree index, calculating the service life influence index of the electric drill, specifically comprising the following steps: acquiring a maximum value of the applied force based on the applied force sequence, and acquiring a component force of the maximum value of the applied force in a direction perpendicular to the working surface; calculating a ratio of the component force to the application force maximum; and calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio. The service life influence index of the electric drill is in an inverse correlation relation with the aging degree index of the electric drill; and the service life influence index of the electric drill is in an inverse correlation with the ratio. The larger the ratio is, the more violent the current personnel use the electric drill; the smaller the value of the influence index of the service life of the electric drill is, the more the service life of the electric drill is influenced by the service state of the current electric drill, and otherwise, the healthier the service state of the current electric drill is.

The force is resolved according to the maximum application force value applied by the electric drill by a person and the angle between the electric drill and the working face corresponding to the maximum application force value, and the component force of the maximum application force value in the direction perpendicular to the working face is obtained.

As an example, the product of the aging degree index of the electric drill and the ratio is obtained, and the reciprocal of the product is the service life influence index of the electric drill.

And step S5, adjusting the power of the electric drill according to the influence index of the service life of the electric drill.

And after the service life influence index of the electric drill is obtained, carrying out normalization processing on the service life influence index of the electric drill, and adjusting the power of the electric drill according to the normalized value.

The threshold value is preset, when the normalized influence index of the service life of the electric drill is larger than the preset threshold value, the current healthier the use state of the electric drill is, the service life of the electric drill is not influenced or not greatly influenced, and at the moment, the power of the electric drill does not need to be adjusted; when the normalized service life influence index of the electric drill is smaller than or equal to the preset threshold value, the fact that the current service state of the electric drill is unhealthy is proved to seriously influence the service life of the electric drill, at the moment, the power of the electric drill needs to be continuously and slowly reduced to enable the electric drill to work at low power or continuously and slowly reduce the power until the electric drill stops working, and the normal working power is recovered after the electric drill works at low power or stops working for a period of time.

Based on the same inventive concept as the method embodiment, an embodiment of the present invention provides a power drill power calculation system based on a spindle offset load field analysis, please refer to fig. 2, which shows a module configuration diagram of the power drill power calculation system based on the spindle offset load field analysis, the system includes a data acquisition module, a loss index calculation module, an aging degree index calculation module, a power drill service life influence index calculation module and a power adjustment module, specifically:

the data acquisition module is used for acquiring the offset distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by personnel on the basis of a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

the loss index calculation module is used for calculating the loss index of the electric drill based on the offset distance sequence and the abrasion loss sequence;

the aging degree index calculation module is used for calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

the electric drill service life influence index calculation module is used for calculating an electric drill service life influence index based on the application force sequence and the aging degree index;

and the power adjusting module is used for adjusting the power of the electric drill according to the influence indexes of the service life of the electric drill.

Further, the loss index calculation module includes:

a wear amount range acquisition unit configured to acquire a variance of the offset distance based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence;

the range mapping unit is used for carrying out positive correlation mapping on the range to obtain a range mapping value;

and the first calculating unit is used for calculating the product of the variance and the range mapping value to obtain the loss index of the electric drill.

Further, the aging degree index calculation module comprises:

a difference sequence obtaining unit, configured to obtain a difference between each internal temperature in the internal temperature sequence and a room temperature at a corresponding time, so as to obtain a temperature difference sequence;

the temperature difference range acquiring unit is used for acquiring the range of the temperature difference based on the temperature difference sequence;

and the second calculating unit is used for calculating the product of the extreme difference of the temperature difference value and the loss index of the electric drill to obtain the aging degree index of the electric drill.

Further, the electric drill service life influence index calculation module comprises:

the ratio acquisition unit is used for acquiring a maximum value of the applied force based on the applied force sequence and acquiring a component force of the maximum value of the applied force in a direction vertical to the working surface; calculating a ratio of the force component to the force application maximum;

and the third calculating unit is used for calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio.

Further, the service life influence index of the electric drill and the aging degree index of the electric drill are in an inverse correlation relationship; and the influence index of the service life of the electric drill is in an inverse correlation relation with the ratio.

It should be noted that: the sequence of the above embodiments of the present invention is only for description, and does not represent the advantages or disadvantages of the embodiments. And specific embodiments thereof have been described above. Other embodiments are within the scope of the following claims. In some cases, the actions or steps recited in the claims may be performed in a different order than in the embodiments and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing may also be possible or may be advantageous.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. A power calculation method of an electric drill based on spindle bias load field analysis is characterized by comprising the following steps:

acquiring the offset distance of an electric drill bit, the internal temperature of the electric drill, the abrasion loss of the electric drill bit and the force applied to the electric drill by personnel based on a preset time interval to obtain an offset distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

calculating a loss index of the electric drill based on the offset distance sequence and the wear amount sequence;

calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

calculating the service life influence index of the electric drill based on the force application sequence and the aging degree index;

adjusting the power of the electric drill according to the influence indexes of the service life of the electric drill; calculating a loss index of the electric drill based on the offset distance sequence and the abrasion loss sequence, specifically:

acquiring a variance of offset distances based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence;

carrying out positive correlation mapping on the range to obtain a range mapping value;

and the product of the variance and the range mapping value is a loss index of the electric drill.

2. The method for calculating power of the electric drill based on the in-situ analysis of the spindle offset load as claimed in claim 1, wherein an aging degree index of the electric drill is calculated based on the internal temperature sequence and the loss index, and specifically comprises the following steps:

obtaining the difference value between each internal temperature in the internal temperature sequence and the room temperature at the corresponding moment to obtain a temperature difference value sequence;

acquiring the range of the temperature difference value based on the temperature difference value sequence;

and the product of the extreme difference of the temperature difference value and the loss index of the electric drill is the aging degree index of the electric drill.

3. The method for calculating power of the electric drill based on the in-situ analysis of the spindle offset load as claimed in claim 2, wherein the method for calculating the service life influence index of the electric drill based on the applied force sequence and the aging degree index comprises the following specific steps:

acquiring a maximum value of the application force based on the application force sequence, and acquiring a component force of the maximum value of the application force in a direction perpendicular to the working surface; calculating a ratio of the force component to the force application maximum;

and calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio.

4. The method of claim 3 in which the drill life impact indicator is inversely related to the drill age indicator; and the service life influence index of the electric drill is in an inverse correlation with the ratio.

5. A power drill power calculation system based on in situ analysis of spindle bias load, the system comprising:

the data acquisition module is used for acquiring the deflectable distance of the drill bit of the electric drill, the internal temperature of the electric drill, the abrasion loss of the drill bit and the force applied to the electric drill by personnel based on a preset time interval to obtain a deflection distance sequence, an internal temperature sequence, an abrasion loss sequence and a force applying sequence; the applied force is the force applied to the electric drill by a person;

the loss index calculation module is used for calculating the loss index of the electric drill based on the offset distance sequence and the abrasion loss sequence;

the aging degree index calculation module is used for calculating an aging degree index of the electric drill based on the internal temperature sequence and the loss index;

the electric drill service life influence index calculation module is used for calculating an electric drill service life influence index based on the application force sequence and the aging degree index;

the power adjusting module is used for adjusting the power of the electric drill according to the service life influence indexes of the electric drill;

wherein, loss index calculation module includes:

a wear amount range acquisition unit configured to acquire a variance of the offset distance based on the offset distance sequence; acquiring the range of the abrasion loss based on the abrasion loss sequence;

the range mapping unit is used for carrying out positive correlation mapping on the range to obtain a range mapping value;

and the first calculation unit is used for calculating the product of the variance and the range mapping value to obtain the loss index of the electric drill.

6. The drill power calculation system based on in situ analysis of spindle bias load of claim 5, wherein the degradation indicator calculation module comprises:

a difference sequence obtaining unit, configured to obtain a difference between each internal temperature in the internal temperature sequence and a room temperature at a corresponding time, so as to obtain a temperature difference sequence;

the temperature difference range acquiring unit is used for acquiring the range of the temperature difference based on the temperature difference sequence;

and the second calculating unit is used for calculating the product of the extreme difference of the temperature difference value and the loss index of the electric drill to obtain the aging degree index of the electric drill.

7. The power drill power calculation system based on spindle bias load in-situ analysis of claim 6, wherein the power drill service life impact indicator calculation module comprises:

the ratio acquisition unit is used for acquiring a maximum value of the applied force based on the applied force sequence and acquiring a component force of the maximum value of the applied force in the direction vertical to the working surface; calculating a ratio of the force component to the force application maximum;

and the third calculating unit is used for calculating the service life influence index of the electric drill according to the aging degree index of the electric drill and the ratio.

8. The power calculation system for a power drill based on in situ analysis of spindle offset load of claim 7 wherein the drill life impact indicator is inversely related to the drill age indicator; and the service life influence index of the electric drill is in an inverse correlation with the ratio.

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