JP7046300B1 - How to control polygon wear on wheels of railway transportation vehicles - Google Patents
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Abstract
【課題】鉄道輸送車両の車輪のポリゴン摩耗の制御方法を提供する。【解決手段】鉄道輸送車両のポリゴン摩耗の車輪情報を収集し、車輪のポリゴン摩耗の追跡試験を行い、車輪のポリゴン摩耗データを取得するステップと、車輪摩耗速度および車輪の踏み面の焼き入れ強化材料の摩耗特性に応じて、谷位置の車輪の選択エリアの強化パラメータを合わせて設計するステップと、強化パラメータに基づいて、車輪の踏み面の選択エリアの焼き入れ強化技術を使用して、車輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン摩耗における山と谷位置の摩耗相対的な速度比を増加させるステップと、車輪のポリゴン摩耗における山と谷間の振幅が一定値まで減少し、谷位置の強化材料の摩耗がなくなると、車輪の踏み面に対して均一な選択エリア強度処理を行うステップとを含む。【選択図】図1PROBLEM TO BE SOLVED: To provide a method for controlling polygon wear of wheels of a railway transport vehicle. SOLUTION: The step of collecting wheel information of polygon wear of a railroad transport vehicle, performing a tracking test of the polygon wear of the wheel, acquiring the polygon wear data of the wheel, and strengthening the quenching of the wheel wear speed and the tread surface of the wheel. Wheels using the step of designing the strengthening parameters of the wheel selection area in the valley position according to the wear characteristics of the material and the quenching strengthening technology of the wheel tread selection area based on the strengthening parameters. The step of increasing the relative speed ratio of the wear of the peak and valley position in the polygon wear of the wheel by performing the selection area strengthening process for the valley position of the polygon wear of, and the amplitude of the peak and valley in the polygon wear of the wheel are constant. Includes a step of performing a uniform selection area strength treatment on the tread of the wheel once it has been reduced to the value and the wear of the reinforcement material at the valley position is gone. [Selection diagram] Fig. 1
Description
本発明は、鉄道輸送の技術分野に関し、具体的に鉄道輸送車両の車輪のポリゴン摩耗の制
御方法に関する。
The present invention relates to the technical field of railway transportation, and specifically relates to a method for controlling polygon wear of wheels of a railway transportation vehicle.
従来技術では、鉄道輸送車両の車輪のポリゴン摩耗は、主に車輪の踏み面を回転修理する
ことで改善され、車輪の回転修理は短期間でしか鉄道輸送車両の車輪のポリゴン摩耗状況
を改善できなく、走行時間が経過すると、鉄道輸送車両の車輪のポリゴン摩耗が再び発生
し、車輪の回転修理は、車輪の表面材料を切断してポリゴン摩耗を解消するために使用さ
れ、車輪の耐用年数を短縮し、経済的コストが高くなる。
In the prior art, the polygon wear of the wheels of a rail transport vehicle can be improved mainly by rotationally repairing the tread surface of the wheels, and the rotational repair of the wheels can improve the polygon wear condition of the wheels of the rail transport vehicle only in a short period of time. No, over time, the wheel polygon wear of the rail transport vehicle reoccurs, and the wheel rotation repair is used to cut the wheel surface material to eliminate the polygon wear and extend the wheel's useful life. It will be shortened and the economic cost will be high.
上記の問題を解決するために、本発明は、従来技術における上記欠点を克服することがで
きる鉄道輸送車両の車輪のポリゴン摩耗の制御方法を提供し、具体的な技術的解決策は以
下の通りである。
In order to solve the above problems, the present invention provides a method for controlling polygon wear of wheels of a railway transport vehicle that can overcome the above-mentioned drawbacks in the prior art, and specific technical solutions are as follows. Is.
本発明は鉄道輸送車両の車輪のポリゴン摩耗の制御方法を提供し、
S1、鉄道輸送車両のポリゴン摩耗の車輪情報を収集し、車輪のポリゴン摩耗の追跡試験
を行い、車輪のポリゴン摩耗データを取得するステップと、
S2、車輪摩耗速度および車輪の踏み面の焼き入れ強化材料の摩耗特性に応じて、谷位置
の車輪の選択エリアの強化パラメータを合わせて設計するステップと、
S3、強化パラメータに基づいて、車輪の踏み面の選択エリアの焼き入れ強化技術を使用
して、車輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン
摩耗における山と谷位置の摩耗相対的な速度比を増加させるステップと、
S4、車輪のポリゴン摩耗における山と谷間の振幅が一定値まで減少し、谷位置の強化材
料の摩耗がなくなると、車輪の踏み面に対して均一な選択エリア強度処理を行うステップ
と、を含む。
The present invention provides a method for controlling polygon wear on wheels of a railway transport vehicle.
S1, the step of collecting wheel information of the polygon wear of the railway transport vehicle, performing the tracking test of the polygon wear of the wheel, and acquiring the polygon wear data of the wheel,
S2, the step of designing according to the strengthening parameter of the selection area of the wheel at the valley position according to the wear rate of the wheel and the wear characteristics of the hardened reinforcement material of the tread surface of the wheel.
Based on S3, strengthening parameters, the selection area strengthening process is performed for the valley position of the polygon wear of the wheel using the quenching strengthening technology of the selection area of the tread surface of the wheel, and the peaks and valleys in the polygon wear of the wheel are performed. With steps to increase the wear relative speed ratio of the position,
S4, including a step of performing a uniform selection area strength treatment on the tread surface of the wheel when the amplitude of the peak and the valley in the polygon wear of the wheel is reduced to a certain value and the wear of the reinforcing material at the valley position is eliminated. ..
本発明の一態様によれば、ステップS1において、車輪のポリゴン摩耗追跡試験を行って
、車輪のポリゴン摩耗データを取得する方法は、
S11、定期的に車輪プロファイルを測定し、車輪の標準プロファイルと比較することに
よって、車輪摩耗を取得すること、
S12、レーザプロファイル測定器または接触式プロファイル測定器を使用して、5°ご
とに車輪プロファイルを測定し車輪摩耗量を取得すること、
S13、線形補間法を使用して、全周範囲内の車輪摩耗量を取得すること、を含む。
本発明の一態様によれば、強化パラメータは、強化スポットサイズ、深さおよびピッチを
含む。
According to one aspect of the present invention, in step S1, the method of performing the polygon wear tracking test of the wheel and acquiring the polygon wear data of the wheel is
S11, Obtaining wheel wear by measuring the wheel profile on a regular basis and comparing it with the standard profile of the wheel,
Using S12, a laser profile measuring device or a contact type profile measuring device, measure the wheel profile every 5 ° to obtain the amount of wheel wear.
S13, including obtaining the wheel wear amount within the entire circumference range by using the linear interpolation method.
According to one aspect of the invention, the reinforcement parameters include the reinforcement spot size, depth and pitch.
本発明の一態様によれば、強化パラメータの設計方法は以下の通りであり:車輪円周上の
ある点の摩耗量をSとし、谷と山間の摩耗量の差をΔSとし、強化スポットの深さをhと
し、強化スポットの直径をDとすると、強化領域の材料耐摩耗性がm倍向上し、強化スポ
ットの深さhが以下の式を満たす:
式では、αは調整係数であり、強化領域の位置に関連し、
強化スポットの深さhを取得した後、以下の式に従い強化スポットの直径を計算する:
D=18h
各列の強化スポットのピッチlは以下の式に従って決定され:
式では、Sminは山の摩耗量を表し、βは調整係数であり、強化領域の材料耐摩耗性能
の増加量に関連する。
According to one aspect of the present invention, the method of designing the reinforcement parameter is as follows: the amount of wear at a certain point on the wheel circumference is S, the difference between the amount of wear between valleys and mountains is ΔS, and the reinforcement spot is When the depth is h and the diameter of the reinforced spot is D, the material wear resistance of the reinforced region is improved by m times, and the depth h of the reinforced spot satisfies the following equation:
In the equation, α is the adjustment factor, which is related to the position of the strengthening region.
After obtaining the depth h of the strengthening spot, calculate the diameter of the strengthening spot according to the following formula:
D = 18h
The pitch l of the strengthening spots in each row is determined according to the following formula:
In the equation, S min represents the amount of wear of the mountain, β is the adjustment coefficient, and is related to the amount of increase in the material wear resistance performance of the reinforced region.
本発明の一態様によれば、強化スポットの列と列間のピッチは強化スポット直径の3倍で
ある。
According to one aspect of the invention, the rows of reinforcement spots and the pitch between rows is three times the diameter of the reinforcement spots.
本発明の一態様によれば、ステップS4において、均一な強化処理を行う時、強化スポッ
トの深さが0.7~0.9mmであり、直径が14.3~14.5mmであり、各列の内
部では、強化スポットのピッチが14~16mmであり、列と列間のピッチが39~41
mmである。
According to one aspect of the present invention, in step S4, when the uniform strengthening treatment is performed, the depth of the strengthening spot is 0.7 to 0.9 mm and the diameter is 14.3 to 14.5 mm, respectively. Inside the row, the pitch of the reinforcement spots is 14-16 mm and the pitch between rows is 39-41.
It is mm.
従来の車輪のポリゴン摩耗制御方法と比較すると、本発明の有益な効果は次の通りである
。
(1)本発明は、車輪摩耗速度および車輪の踏み面の焼き入れ強化処理材料の摩耗特性に
基づいて、車輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリ
ゴン摩耗における山と谷位置の摩耗相対速度比を増加し、ポリゴン車輪の踏み面の山と谷
間の振幅を減少して、ポリゴン摩耗の進行を制御することができる。
(2)本発明は、車輪の強度を変更せず、ポリゴン車輪の谷材料の耐磨性能を改善し、車
輪の耐用寿命を大幅に延ばし、コストが車輪の回転修理よりも大幅に低下する。
Compared with the conventional wheel polygon wear control method, the beneficial effects of the present invention are as follows.
(1) In the present invention, the selection area strengthening treatment is performed on the valley position of the polygon wear of the wheel based on the wheel wear speed and the wear characteristics of the hardened strengthening treatment material of the tread surface of the wheel, and the polygon wear of the wheel is achieved. It is possible to control the progress of polygon wear by increasing the wear relative speed ratio of the peak and valley positions and reducing the amplitude of the peak and valley of the tread of the polygon wheel.
(2) The present invention does not change the strength of the wheel, improves the polishing resistance of the valley material of the polygon wheel, greatly extends the service life of the wheel, and the cost is significantly lower than that of the rotation repair of the wheel.
本発明によって達成される方法および効果をさらに説明するために、以下本発明の技術的
解決策を、添付の図面と併せて明確かつ完全に説明する。
In order to further illustrate the methods and effects achieved by the present invention, the technical solutions of the present invention will be described below clearly and completely in conjunction with the accompanying drawings.
実施例1
実施例1は主に本発明の制御方法の具体的なステップを説明し、その内容は以下の通りで
ある。
図1に示すように、本発明によって提供される鉄道輸送車両の車輪のポリゴン摩耗の制御
方法は、
S1、鉄道輸送車両のポリゴン摩耗の車輪情報を収集し、車輪のポリゴン摩耗の追跡試験
を行い、車輪のポリゴン摩耗データを取得するステップと、
S2、車輪摩耗速度および車輪の踏み面の焼き入れ強化材料の摩耗特性に応じて、谷位置
の車輪の選択エリアの強化パラメータを合わせて設計するステップと、
S3、強化パラメータに基づいて、車輪の踏み面の選択エリアの焼き入れ強化技術を使用
して、車輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン
摩耗における山と谷位置の摩耗相対的な速度比を増加させるステップと、
S4、車輪のポリゴン摩耗における山と谷間の振幅が一定値まで減少し、谷位置の強化材
料の摩耗がなくなると、車輪の踏み面に対して均一な選択エリア強度処理を行うステップ
と、を含む。
本発明の一態様によれば、ステップS1において、車輪のポリゴン摩耗追跡試験を行って
、車輪のポリゴン摩耗データを取得する方法は、
S11、定期的に車輪プロファイルを測定し、車輪の標準プロファイルと比較することに
よって、車輪摩耗を取得すること、
S12、レーザプロファイル測定器または接触式プロファイル測定器を使用して、5°ご
とに車輪プロファイルを測定し車輪摩耗量を取得すること、
S13、線形補間法を使用して、全周範囲内の車輪摩耗量を取得すること、を含む。
具体的には、強化パラメータは、強化スポットサイズ、深さおよびピッチを含む。
具体的には、強化パラメータの設計方法は以下の通りであり:車輪円周上のある点の摩耗
量をSとし、谷と山間の摩耗量の差をΔSとし、強化スポットの深さをhとし、強化スポ
ットの直径をDとすると、強化領域の材料耐摩耗性がm倍向上し、強化スポットの深さh
が以下の式を満たす:
式では、αは調整係数であり、強化領域の位置に関連し、
強化スポットの深さhを取得した後、以下の式に従い強化スポットの直径を計算する:
D=18h
各列の強化スポットのピッチlは以下の式に従って決定され:
式では、Sminは山の摩耗量を表し、βは調整係数であり、強化領域の材料耐摩耗性能
の増加量に関連する。
具体的には、強化スポットの列と列間のピッチは強化スポット直径の3倍である。
Example 1
The first embodiment mainly describes the specific steps of the control method of the present invention, and the contents thereof are as follows.
As shown in FIG. 1, the method for controlling polygon wear of wheels of a railway transport vehicle provided by the present invention is as follows.
S1, the step of collecting wheel information of the polygon wear of the railway transport vehicle, performing the tracking test of the polygon wear of the wheel, and acquiring the polygon wear data of the wheel,
S2, the step of designing according to the strengthening parameter of the selection area of the wheel at the valley position according to the wear rate of the wheel and the wear characteristics of the hardened reinforcement material of the tread surface of the wheel.
Based on S3, strengthening parameters, the selection area strengthening process is performed for the valley position of the polygon wear of the wheel using the quenching strengthening technology of the selection area of the tread surface of the wheel, and the peaks and valleys in the polygon wear of the wheel are performed. With steps to increase the wear relative speed ratio of the position,
S4, including a step of performing a uniform selection area strength treatment on the tread surface of the wheel when the amplitude of the peak and the valley in the polygon wear of the wheel is reduced to a certain value and the wear of the reinforcing material at the valley position is eliminated. ..
According to one aspect of the present invention, in step S1, the method of performing the polygon wear tracking test of the wheel and acquiring the polygon wear data of the wheel is
S11, Obtaining wheel wear by measuring the wheel profile on a regular basis and comparing it with the standard profile of the wheel,
Using S12, a laser profile measuring device or a contact type profile measuring device, measure the wheel profile every 5 ° to obtain the amount of wheel wear.
S13, including obtaining the wheel wear amount within the entire circumference range by using the linear interpolation method.
Specifically, the enhancement parameters include enhancement spot size, depth and pitch.
Specifically, the method of designing the strengthening parameters is as follows: the amount of wear at a certain point on the wheel circumference is S, the difference between the amount of wear between valleys and mountains is ΔS, and the depth of the strengthening spot is h. Assuming that the diameter of the reinforced spot is D, the material wear resistance of the reinforced region is improved by m times, and the depth of the reinforced spot is h.
Satisfies the following equation:
In the equation, α is the adjustment factor, which is related to the position of the strengthening region.
After obtaining the depth h of the strengthening spot, calculate the diameter of the strengthening spot according to the following formula:
D = 18h
The pitch l of the strengthening spots in each row is determined according to the following formula:
In the equation, S min represents the amount of wear of the mountain, β is the adjustment coefficient, and is related to the amount of increase in the material wear resistance performance of the reinforced region.
Specifically, the rows of reinforcement spots and the pitch between the rows are three times the diameter of the reinforcement spots.
実施例2
実施例2は実施例1に記載の方法に基づいて強化パラメータを設計したものであり、具体
的な内容は以下の通りである。
ステップS4において、均一な強化処理を行う時、強化スポットの深さが0.7mmであ
り、直径が14.3mmであり、各列の内部では、強化スポットのピッチが14mmであ
り、列と列間のピッチが39mmである。
以上の内容を除いて、実施例2は実施例1の他の部分と同じである。
Example 2
In the second embodiment, the strengthening parameters are designed based on the method described in the first embodiment, and the specific contents are as follows.
In step S4, when the uniform strengthening treatment is performed, the depth of the strengthening spots is 0.7 mm, the diameter is 14.3 mm, and inside each row, the pitch of the strengthening spots is 14 mm, and the rows and rows. The pitch between them is 39 mm.
Except for the above contents, Example 2 is the same as the other parts of Example 1.
実施例3
実施例3は実施例1に記載の方法に基づいて強化パラメータを設計したものであり、具体
的な内容は以下の通りである。
ステップS4において、均一な強化処理を行う時、強化スポットの深さが0.9mmであ
り、直径が14.5mmであり、各列の内部では、強化スポットのピッチが16mmであ
り、列と列間のピッチが41mmである。
以上の内容を除いて、実施例3は実施例1の他の部分と同じである。
Example 3
In the third embodiment, the strengthening parameters are designed based on the method described in the first embodiment, and the specific contents are as follows.
In step S4, when the uniform strengthening treatment is performed, the depth of the strengthening spots is 0.9 mm and the diameter is 14.5 mm, and inside each row, the pitch of the strengthening spots is 16 mm, and the rows and rows. The pitch between them is 41 mm.
Except for the above contents, Example 3 is the same as the other parts of Example 1.
実施例4
実施例4は実施例1に記載の方法に基づいて説明したものであり、具体的な実施例を通じ
て本発明の実際の車輪の修復効果を説明し、図1は本実施例の効果を示す図である。
強化パラメータに基づいて、車輪の踏み面の選択エリアの焼き入れ強化技術により、車輪
のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン摩耗におけ
る山と谷位置の摩耗相対速度比を増加させ、図2に示すように、このとき、谷位置の車輪
材料の摩耗速度が大幅に低下し、谷以外の位置の車輪材料の摩耗速度が変更せず、車両の
走行時間が経過すると、車輪の山と谷間の振幅が減少する。
図3に示すように、線形補間法を使用して、車両が15万km走行しているときの車輪の
全周範囲内の摩耗量を取得し、図3のデータから分かるように、車輪の山と谷の摩耗速度
比が穏やかであり、これは、本発明によって設計された制御方法は車輪のポリゴン摩耗の
進行を効果的に抑制することを示す。
Example 4
Example 4 has been described based on the method described in Example 1, and the actual wheel repair effect of the present invention will be described through specific examples, and FIG. 1 is a diagram showing the effect of the present embodiment. Is.
Based on the strengthening parameters, the selection area strengthening process is performed for the valley position of the polygon wear of the wheel by the quenching strengthening technology of the selection area of the tread surface of the wheel, and the wear relative speed of the peak and valley position in the polygon wear of the wheel. As shown in FIG. 2, the ratio is increased, and at this time, the wear rate of the wheel material at the valley position is significantly reduced, the wear speed of the wheel material at the position other than the valley is not changed, and the traveling time of the vehicle elapses. Then, the amplitude of the peaks and valleys of the wheels decreases.
As shown in FIG. 3, the linear interpolation method is used to obtain the amount of wear within the entire circumference range of the wheel when the vehicle is traveling 150,000 km, and as can be seen from the data of FIG. 3, the wheel The wear rate ratio between peaks and valleys is mild, indicating that the control method designed by the present invention effectively suppresses the progression of wheel polygon wear.
実験例
本実験例は上記の実施例1に記載の測定方法に基づいて説明したものであり、シミュレー
ション法によってこの方法によるポリゴン車輪摩耗の修復効果を調べることを目的とする
。
以下、本発明の具体的な実施効果を説明する。
本実験例で使用される車両の走行安定性の評価式は以下の通りである。
Wは安定性指数であり、Aは振動加速度(g)であり、fは振動周波数(Hz)であり、
F(f)は周波数修正係数である。
本実験例で使用される車両の走行安定性の評価標準は表1に示される。
表1車両の走行安定性のレベル
Experimental Example This experimental example has been described based on the measurement method described in Example 1 above, and an object of the present invention is to investigate the repair effect of polygon wheel wear by this method by a simulation method.
Hereinafter, specific implementation effects of the present invention will be described.
The evaluation formula for the running stability of the vehicle used in this experimental example is as follows.
W is the stability index, A is the vibration acceleration (g), f is the vibration frequency (Hz), and
F (f) is a frequency correction coefficient.
Table 1 shows the evaluation standards for the running stability of the vehicle used in this experimental example.
Table 1 Vehicle running stability level
1、車輪のポリゴンパラメータ
本実験のシミュレーションでは、車両の走行中に、車輪の多角化によって車両に垂直方向
の振動が与えられ、サスペンションシステムによって減衰された後車体に伝達される。未
処理のポリゴン車輪の場合、速度と高調波次数が異なるポリゴンによって引き起こされる
対応する振動周波数は表2に示される。
表2強化処理されていない車輪のポリゴンによって引き起こされる振動周波数
1. Wheel polygon parameters In the simulation of this experiment, while the vehicle is running, the diversification of the wheels gives the vehicle vertical vibration, which is attenuated by the suspension system and then transmitted to the vehicle body. For unprocessed polygon wheels, the corresponding vibration frequencies caused by polygons with different velocities and harmonic orders are shown in Table 2.
Table 2 Vibration frequencies caused by unreinforced wheel polygons
未処理のポリゴン車輪について、波の深さと車速の場合、15次の車輪のポリゴンを選択
して安定性を測定し、安定性の結果が表3-1および表3-2に示される。
表3-1未処理のポリゴン車輪の垂直方向の安定性
For unprocessed polygon wheels, for wave depth and vehicle speed, 15th order wheel polygons are selected and stability is measured and the stability results are shown in Tables 3-1 and 3-2.
Table 3-1 Vertical stability of unprocessed polygon wheels
表3-2未処理のポリゴン車輪の横方向の安定性 Table 3-2 Lateral stability of unprocessed polygon wheels
表1の評価標準を合わせて、表3-1および表3-2から分かるように、シミュレーション
された車両の走行速度が50km/h未満の時、車輪の安定性が優秀レベルに達する可能
性があり、シミュレーションされた車両の走行速度が50~150km/hである時、車
輪の安定性が基本的に合格であるが、シミュレーションされた車両の走行速度が150k
m/hを超える時、車輪の安定性が合格標準を満たさない。
摩耗のシミュレーション過程中、制御された摩耗の限界はそれぞれ0.1mm、0.05
mm、0.02mmであり、速度100km/h、15次の車輪のポリゴン、波の深さ0
.05mmの未処理ポリゴン車輪の摩耗進行傾向を計算して表4に示される。
表4 未処理のポリゴン車輪の真円でないオフセット値
Combined with the evaluation criteria in Table 1, as can be seen from Table 3-1 and Table 3-2, when the simulated vehicle speed is less than 50 km / h, the wheel stability may reach an excellent level. Yes, when the running speed of the simulated vehicle is 50-150km / h, the stability of the wheels is basically acceptable, but the running speed of the simulated vehicle is 150k.
When it exceeds m / h, the stability of the wheel does not meet the acceptance standard.
During the wear simulation process, the controlled wear limits are 0.1 mm and 0.05, respectively.
mm, 0.02 mm, velocity 100 km / h, 15th-order wheel polygon,
.. The wear progress tendency of the 05 mm untreated polygon wheel is calculated and shown in Table 4.
Table 4 Non-circular offset values for unprocessed polygon wheels
表4のデータから分かるように、最大の摩耗量が0.05mmから0.1mmに変更する
過程中に、車輪の円周プロファイルが大幅に変化する。そして車両走行の初期階段ではポ
リゴン車輪の山と谷の摩耗速度が小さいが、車両の走行距離が長くなると、谷の摩耗速度
が明らかに増加し、長期間の摩耗の後車両に顕著な谷が形成される。
As can be seen from the data in Table 4, the circumferential profile of the wheel changes significantly during the process of changing the maximum wear from 0.05 mm to 0.1 mm. And while the wear speed of the peaks and valleys of the polygon wheels is small in the initial stairs of vehicle running, the wear speed of the valleys clearly increases as the vehicle travels longer, and after a long period of wear, the vehicle has noticeable valleys. It is formed.
2、車輪のポリゴンの強化処理
上記の実施例のステップS4に記載の方法により、ポリゴン車輪に対して均一な強化処理
を行い、強化スポットの深さが0.8mmであり、直径が14.4mmであり、各列の内
部では、強化スポットのピッチが15mmであり、列と列間のピッチが40mmである。
処理されたポリゴン車輪について、速度と高調波次数が異なるポリゴンによって引き起こ
される対応する振動周波数が表5に示される。
表5 強化処理された車輪のポリゴンによって引き起こされる振動周波数
2. Reinforcement processing of polygons of wheels By the method described in step S4 of the above embodiment, the polygon wheels are uniformly strengthened, the depth of the reinforcement spot is 0.8 mm, and the diameter is 14.4 mm. Inside each row, the pitch of the reinforcement spots is 15 mm and the pitch between rows is 40 mm.
For the treated polygon wheels, the corresponding vibration frequencies caused by polygons with different velocities and harmonic orders are shown in Table 5.
Table 5 Vibration frequencies caused by reinforced wheel polygons
処理されたポリゴン車輪について、波の深さと車速が異なる場合、15次の車輪のポリゴ
ンを選択して安定性を測定し、安定性の結果が表6-1および表6-2に示される。
表6-1 処理されたポリゴン車輪の垂直方向の安定性
For the treated polygon wheels, if the wave depth and vehicle speed are different, the polygons of the 15th order wheels are selected and the stability is measured and the stability results are shown in Tables 6-1 and 6-2.
Table 6-1 Vertical stability of treated polygon wheels
表6-2 処理されたポリゴン車輪の横方向の安定性 Table 6-2 Lateral stability of treated polygon wheels
表1の評価標準を合わせて、表6-1および表6-2から分かるように、シミュレーション
された車両の走行速度が50~250km/hである時、車輪の安定性が優秀レベルに達
する可能性がある。
Combined with the evaluation criteria in Table 1, as can be seen from Tables 6-1 and 6-2, wheel stability can reach excellent levels when the simulated vehicle speed is 50-250 km / h. There is sex.
摩耗のシミュレーション過程中に、制御された摩耗の限界がそれぞれ0.1mm、0.0
5mm、0.02mmであり、速度100km/h、15次の車輪のポリゴン、波の深さ
0.05mmの処理されたポリゴン車輪の摩耗進行傾向を計算して表7に示される。
表7 処理されたポリゴン車輪の真円でないオフセット値
During the wear simulation process, the controlled wear limits are 0.1 mm and 0.0, respectively.
Table 7 calculates the wear progress tendency of the treated polygon wheels having a speed of 5 mm and 0.02 mm, a speed of 100 km / h, a polygon of the 15th-order wheel, and a wave depth of 0.05 mm.
Table 7 Non-circular offset values for processed polygon wheels
表7のデータから分かるように、最大の摩耗量が0.05mmから0.1mmに変更する
過程中に、車輪の円周プロファイルが大幅に変化しない。そして車両走行の初期階段では
ポリゴン車輪の山と谷の摩耗速度が小さく、車両の走行距離が増加すると、谷の摩耗速度
が増加するがそれほど顕著ではない。これは、車輪の踏み面の選択エリアの焼き入れ強化
技術により、ポリゴン摩耗の進行を効果的に制御することができるのを示す。
表5と表2、表6-1と表3-1、表6-2と表3-2、表7と表4中のデータをそれぞれ比
較して分かるように、本発明は車輪の踏み面の選択エリアの焼き入れ強化技術により、車
輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン摩耗にお
ける山と谷位置の摩耗相対速度比を増加させ、山位置の車輪材料の摩耗速度を増加して谷
位置の車輪材料の摩耗速度を減少することで車輪のポリゴン摩耗の進行を総合的に制御し
、ポリゴン車輪の安定性を高める。
As can be seen from the data in Table 7, the circumference profile of the wheel does not change significantly during the process of changing the maximum wear amount from 0.05 mm to 0.1 mm. In the initial stairs of vehicle running, the wear speed of the peaks and valleys of the polygon wheels is small, and as the mileage of the vehicle increases, the wear speed of the valleys increases, but it is not so remarkable. This indicates that the progress of polygon wear can be effectively controlled by the quenching strengthening technique of the selection area of the tread surface of the wheel.
As can be seen by comparing the data in Table 5 and Table 2, Table 6-1 and Table 3-1 and Table 6-2 and Table 3-2, and Table 7 and Table 4, respectively, the present invention presents the wheel tread. The selection area strengthening process is performed for the valley position of the polygon wear of the wheel by the hardening strengthening technology of the selection area, and the wear relative speed ratio of the peak and valley position in the polygon wear of the wheel is increased, and the wheel material of the mountain position is used. By increasing the wear rate of the wheel and decreasing the wear rate of the wheel material at the valley position, the progress of polygon wear of the wheel is comprehensively controlled, and the stability of the polygon wheel is improved.
Claims (3)
を行い、車輪のポリゴン摩耗データを取得するステップと、
S2、車輪摩耗速度および車輪の踏み面の焼き入れ強化材料の摩耗特性に応じて、谷位置
の車輪の選択エリアの強化パラメータを合わせて設計するステップと、
S3、強化パラメータに基づいて、車輪の踏み面の選択エリアの焼き入れ強化技術を使用
して、車輪のポリゴン摩耗の谷位置に対して選択エリア強化処理を行い、車輪のポリゴン
摩耗における山と谷位置の摩耗相対的な速度比を増加させるステップと、
S4、車輪のポリゴン摩耗における山と谷間の振幅が一定値まで減少し、谷位置の強化材
料の摩耗がなくなると、車輪の踏み面に対して均一な選択エリア強度処理を行うステップ
と、
を含むことを特徴とする鉄道輸送車両の車輪のポリゴン摩耗の制御方法。 S1, the step of collecting wheel information of the polygon wear of the railway transport vehicle, performing the tracking test of the polygon wear of the wheel, and acquiring the polygon wear data of the wheel,
S2, the step of designing according to the strengthening parameter of the selection area of the wheel at the valley position according to the wear rate of the wheel and the wear characteristics of the hardened reinforcement material of the tread surface of the wheel.
Based on S3, strengthening parameters, the selection area strengthening process is performed for the valley position of the polygon wear of the wheel using the quenching strengthening technology of the selection area of the tread surface of the wheel, and the peaks and valleys in the polygon wear of the wheel are performed. With steps to increase the wear relative speed ratio of the position,
S4, when the amplitude of the peaks and valleys in the polygon wear of the wheel is reduced to a certain value and the wear of the reinforcing material at the valley position is eliminated, a step of performing a uniform selection area strength treatment on the tread surface of the wheel, and
A method of controlling polygon wear on wheels of a rail transport vehicle, comprising:
タを取得するステップは、
S11、定期的に車輪プロファイルを測定し、車輪の標準プロファイルと比較することに
よって、車輪摩耗を取得すること、
S12、レーザプロファイル測定器または接触式プロファイル測定器を使用して、5°ご
とに車輪プロファイルを測定し車輪摩耗量を取得すること、
S13、線形補間法を使用して、全周範囲内の車輪摩耗量を取得すること、
を含むことを特徴とする請求項1に記載の鉄道輸送車両の車輪のポリゴン摩耗の制御方法
。 In step S1, the step of performing the wheel polygon wear tracking test and acquiring the wheel polygon wear data is
S11, Obtaining wheel wear by measuring the wheel profile on a regular basis and comparing it with the standard profile of the wheel,
Using S12, a laser profile measuring device or a contact type profile measuring device, measure the wheel profile every 5 ° to obtain the amount of wheel wear.
S13, Obtaining the amount of wheel wear within the entire circumference using the linear interpolation method,
The method for controlling polygon wear of wheels of a railway transport vehicle according to claim 1, wherein the method comprises.
求項1に記載の鉄道輸送車両の車輪のポリゴン摩耗の制御方法。 The method for controlling polygon wear on wheels of a rail transport vehicle according to claim 1, wherein the reinforcement parameters include a reinforcement spot size, depth and pitch.
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