CN106206222B8

CN106206222B8 - Cathode-ray magnetic following response speed training device

Info

Publication number: CN106206222B8
Application number: CN201610633937.1A
Authority: CN
Inventors: 葛利民
Original assignee: Donghai Li Min Solar Technology Co ltd
Current assignee: Donghai Tongcheng Quartz Material Technology Co ltd
Priority date: 2015-06-30
Filing date: 2015-06-30
Publication date: 2018-01-26
Anticipated expiration: 2035-06-30
Also published as: CN106206222A; CN106298426A; CN106683961A; CN106098526A; CN104966656A; CN106206222B; CN106683961B; CN106098526B; CN106298426B; CN104966656B

Abstract

The invention discloses a kind of cathode-ray magnetic following response speed training device, cathode-ray tube is fixed on platform by support, and cathode-ray is horizontal；Upper permanent magnet is located above cathode-ray tube, upper sliding pair is provided with above cathode-ray tube, the stationary part of upper sliding pair is connected on platform by support, the sliding part of upper permanent magnet and upper sliding pair connects as one, the glide direction of the sliding part of upper sliding pair is vertical direction, the sliding part of upper sliding pair is hinged with connecting rod, and rod hinge connection is connected with crank, and crank is connected with drive mechanism；Lower permanent magnet is located at below cathode-ray tube, lower slider pair is provided with below cathode-ray tube, the secondary stationary part of lower slider is connected on platform by support, the lower permanent magnet sliding part secondary with lower slider connects as one, the glide direction of the secondary sliding part of lower slider is vertical direction, and the secondary sliding part of lower slider is connected with handle；Upper permanent magnet and lower permanent magnet homopolarity are relative and vertically aligned.

Description

阴极射线磁追踪反应速度训练装置Cathode ray magnetic tracing reaction speed training device

[0001] 本申请是申请号为201510375810X、发明创造名称为阴极射线磁追踪反应速度训练装置、申请日为2015年6月30日的发明专利申请的分案申请。This application is that application number is 201510375810X, invention creation name is cathode ray magnetic tracing reaction speed training device, and the application date is the divisional application of the invention patent application on June 30, 2015.

技术领域technical field

[0002] 本发明涉及一种手眼协调反应速度训练器械，特别是涉及一种阴极射线磁追踪反应速度训练装置。The present invention relates to a kind of hand-eye coordination reaction speed training apparatus, particularly relate to a kind of cathode ray magnetic tracing reaction speed training device. Background technology

背景技术Background technique

[0003] 生活中，人们参加各项运动及活动，其运动的质量都和人的反应速度有直接关系，动作敏捷反应速度快的人更容易获胜，进而在平时训练中也就十分的关注反应速度的训练，反应速度的提升不仅可以取得更好地运动成绩，还可以联动提高思维的敏捷性，这样反应速度训练就有了更广的应用。经过经验总结，反应速度训练有了更好地理论支撑，从场景进入人的视觉***到做出动作反应的时间通过合理的训练是可以缩短的，现在的这方面的训练，都是在实际运动当中反复的重复一些动作来实施的，都是通过实战训练中选择最佳反应时机，但受场地等环境影响并不是都可以随时开展，并且训练的负荷也大，如何减轻训练强度，利用合适的场地实战外的训练器械进行反应速度训练是一条捷径，但这样器械仍有待于开发。In life, people participate in various sports and activities, and the quality of its motion all has direct relationship with people's reaction speed, and the people with swift action and fast reaction speed are more likely to win, and then also just pay close attention to reaction very much in training at ordinary times Speed training and the improvement of reaction speed can not only achieve better sports performance, but also improve the agility of thinking, so that reaction speed training has a wider application. After summing up experience, the reaction speed training has better theoretical support. The time from the scene entering the human visual system to the action response can be shortened through reasonable training. The current training in this area is all based on actual sports. Among them, some actions are repeated repeatedly, and the best response time is selected in actual combat training. However, due to the influence of the venue and other environments, not all of them can be carried out at any time, and the training load is also heavy. How to reduce the training intensity and use appropriate It is a shortcut to train reaction speed with training equipment outside the actual field combat, but such equipment still needs to be developed.

发明内容Contents of the invention

[0004]为了解决上述问题，本发明提供了一种阴极射线磁追踪反应速度训练装置。Summary of the invention In order to solve the above problems, the invention provides a kind of cathode ray magnetic tracing reaction speed training device.

[0005] 本发明采用的技术方案为：一种阴极射线磁追踪反应速度训练装置，其特征在于包括阴极射线管、上永磁体和下永磁体;阴极射线管通过支架固定在平台上，阴极射线呈水平状态;上永磁***于阴极射线管上方，阴极射线管上方设有上滑动副，上滑动副的静止部通过支架连接在平台上，上永磁体与上滑动副的滑动部连接为一体，上滑动副的滑动部的滑动方向为竖直方向，上滑动副的滑动部铰接有连杆，连杆铰接连接有曲柄，曲柄连接有驱动机构;下永磁***于阴极射线管下方，阴极射线管下方设有下滑动副，下滑动副的静止部通过支架连接在平台上，下永磁体与下滑动副的滑动部连接为一体，下滑动副的滑动部的滑动方向为竖直方向，下滑动副的滑动部连接有手柄;上永磁体和下永磁体同极相对，且垂直方向对齐。The technical scheme that the present invention adopts is: a kind of cathode ray magnetic tracing reaction speed training device, it is characterized in that comprising cathode ray tube, upper permanent magnet and lower permanent magnet; The cathode ray tube is fixed on the platform by support, and the cathode ray It is in a horizontal state; the upper permanent magnet is located above the cathode ray tube, and an upper sliding pair is arranged above the cathode ray tube. The stationary part of the upper sliding pair is connected to the platform through a bracket, and the upper permanent magnet is integrated with the sliding part of the upper sliding pair. The sliding direction of the sliding portion of the upper sliding pair is the vertical direction, the sliding portion of the upper sliding pair is hinged with a connecting rod, the connecting rod is hingedly connected with a crank, and the crank is connected with a driving mechanism; the lower permanent magnet is located below the cathode ray tube, and the cathode ray tube There is a lower sliding pair below, the static part of the lower sliding pair is connected to the platform through a bracket, the lower permanent magnet is connected with the sliding part of the lower sliding pair as a whole, the sliding direction of the sliding part of the lower sliding pair is the vertical direction, and the lower sliding The sliding part of the pair is connected with a handle; the upper permanent magnet and the lower permanent magnet are opposite with each other and aligned vertically.

[0006] 进一步的，所述上永磁体通过一弹簧与上滑动副的滑动部连接。Further, described upper permanent magnet is connected with the sliding part of upper sliding pair by a spring.

[0007] 进一步的，所述上滑动副的静止部通过上导轨与支架相连，下滑动副的静止部通过下导轨与支架相连，上导轨和下导轨的运动方向均为水平方向。Further, the static portion of the upper sliding pair is connected with the support by the upper guide rail, and the stationary portion of the lower sliding pair is connected with the support by the lower guide rail, and the direction of motion of the upper guide rail and the lower guide rail is horizontal.

[0008] 进一步的，所述阴极射线管内阴极射线左、右分别设有竖直的左荧光板和右荧光板。Further, the cathode ray left and right in the cathode ray tube are respectively provided with a vertical left fluorescent plate and a right fluorescent plate.

[0009^进一步的，所述阴极射线管内左、右荧光板分别固定连接有左基板、右基板，阴极射线管内设有与其壳***置相对固定的支撑架，左基板通过配合的左导柱、左导套与支撑架连接，右基板通过配合的右导柱、右导套与支撑架连接，左基板、右基板上分别铰接有长度相同的左连杆和右连杆，左连杆和右连杆另一端靠近铰接在一传动块上，传动块上设有螺纹，与该螺纹配合设有轴向位置固定的旋转驱动块，旋转驱动块轴向外端靠近阴极射线管壳体处设有与旋转驱动块同轴旋转的导体片，对应导体片在阴极射线管壳体外设有旋转磁驱动机构。Further, the left and right fluorescent plates in the cathode ray tube are respectively fixedly connected with a left base plate and a right base plate, and a support frame relatively fixed with its housing position is provided in the cathode ray tube, and the left base plate passes through the left guide post, The left guide sleeve is connected with the support frame, and the right base plate is connected with the support frame through the matching right guide column and right guide sleeve. The left base plate and the right base plate are respectively hinged with a left connecting rod and a right connecting rod with the same length. The other end of the connecting rod is hinged close to a transmission block, and the transmission block is provided with a screw thread, which cooperates with the screw thread to provide a rotary drive block with a fixed axial position. The conductor sheet rotates coaxially with the rotary drive block, and a rotating magnetic drive mechanism is provided outside the cathode ray tube casing corresponding to the conductor sheet.

[0010] 进一步的，所述旋转磁驱动机构为一与导体片形状相同的驱动永磁体，驱动永磁体连接有旋转柄。Further, described rotary magnetic driving mechanism is a drive permanent magnet identical with conductor sheet shape, and drive permanent magnet is connected with rotating handle.

[0011] 进一步的，所述旋转磁驱动机构为一与导体片形状相同的电磁铁，电磁铁连接有驱动电机，驱动电机驱动电磁铁的旋转轴线与旋转驱动块同轴。Further, described rotating magnetic driving mechanism is an electromagnet identical with conductor sheet shape, and electromagnet is connected with drive motor, and the axis of rotation of drive motor drives electromagnet is coaxial with rotary drive block.

[0012] 进一步的，所述电磁铁线圈与驱动电机供电回路串联，电磁铁线圈通过导电滑环与供电回路连接。Further, described electromagnet coil is connected in series with drive motor power supply circuit, and electromagnet coil is connected with power supply circuit by conductive slip ring.

[0013] 进一步的，所述导体片为两片以上，以旋转驱动块轴线为轴周向均匀阵列分布，驱动永磁体数量和位置与导体片对应。Further, described conductor piece is more than two pieces, is that axis circumferential uniform array is distributed with rotating drive block axis, drives permanent magnet quantity and position and conductor piece Correspondence.

[0014] 进一步的，所述左、右导柱分别与左、右荧光板垂直。[0014] Further, the left and right guide columns are respectively perpendicular to the left and right fluorescent plates.

[0015] 进一步的，所述左导柱上端、右导柱下端分别向同一方向倾斜。Further, the upper end of the left guide post and the lower end of the right guide post are respectively inclined to the same direction.

[0016] 进一步的，所述与导体片位置相对的阴极射线管壳体设有向内凹陷，呈喇叭状。[0016] Further, the cathode ray tube housing opposite to the conductor sheet position is provided with an inward recess, which is trumpet-shaped.

[0017] 进一步的，上永磁体、下永磁体是同一规格的永磁体。Further, upper permanent magnet, lower permanent magnet are the permanent magnets of same specification.

[0018] 本发明使用时，阴极射线管通电产生电子束，电子束受上永磁体往复运动作用发生偏转波动，此时受训人员手持下永磁体随上永磁体的动作做出反应，使下永磁体对电子束产生一个与上永磁体相位相反的变化磁场，以平衡上永磁体对电子束的作用，使电子束趋于平直，如果训练中电子束变化幅度较大，说明受训人员的反应速度较慢，通过调节上永磁体运动速度可以适应不同难度等级的训练。本装置训练不受场地制约，训练负荷小，可以提高反应速度和时机判断能力，作为实战以外的训练，效果显著，还可以用于儿童感觉统合的训练，训练器手眼协调能力。When the present invention uses, cathode ray tube energizes and produces electron beam, and electron beam is subjected to upper permanent magnet reciprocating action to take place deflection fluctuation, and trainee now holds down permanent magnet and reacts with the action of upper permanent magnet, makes lower permanent magnet The magnet generates a changing magnetic field opposite to the phase of the upper permanent magnet on the electron beam to balance the effect of the upper permanent magnet on the electron beam and make the electron beam tend to be straight. If the electron beam changes greatly during training, it indicates the trainee’s reaction The speed is relatively slow, and it can adapt to training of different difficulty levels by adjusting the moving speed of the upper permanent magnet. The training of this device is not restricted by the venue, the training load is small, and it can improve the reaction speed and timing judgment ability. As a training other than actual combat, the effect is remarkable. It can also be used for children's sensory integration training and trainer hand-eye coordination ability.

附图说明Description of drawings

[0019] 图1为本发明实施例一整体结构示意图。Fig. 1 is a schematic diagram of an overall structure of an embodiment of the present invention.

[0020] 图2为本发明实施例二阴极射线管整体结构示意图。[0020] FIG. 2 is a schematic diagram of the overall structure of a cathode ray tube according to Embodiment 2 of the present invention.

[0021] 图3为本发明实施例二纵刨结构示意图。Fig. 3 is the schematic diagram of the second longitudinal planing structure of the embodiment of the present invention.

[0022] 图4为本发明实施例二内部结构示意图。Fig. 4 is the internal structure schematic diagram of embodiment two of the present invention.

[0023] 图5为本发明实施例二横剖结构示意图。Fig. 5 is the cross-sectional structure schematic diagram of embodiment two of the present invention.

[0024] 图6为本发明电磁式旋转磁驱动机构示意图。Fig. 6 is the schematic diagram of electromagnetic rotary magnetic drive mechanism of the present invention.

[0025] 图7为本发明实施例三横剖结构示意图。Fig. 7 is a schematic diagram of the cross-sectional structure of the third embodiment of the present invention.

[0026] 图8为本发明上永磁体通过弹簧连接结构图。Fig. 8 is the connection structure diagram of permanent magnet by spring in the present invention.

[0027] 图中标号名称：1阴极射线管;2上永磁体;3下永磁体;4平台；5上滑动副的静止部； 6上滑动副的滑动部;7连杆;8左导槽;9曲柄；10电机；11下滑动副的静止部；12下滑动副的滑动部；13手柄；14上导轨；15下导轨；16左荧光板；17右荧光板；18左基板；19右基板;20支撑架;21左导柱;22左导套;23右导柱;24右导套;25左连杆;26右连杆;27传动块;28旋转驱动块;29导体片；30驱动永磁体;31旋转柄;32电磁铁;33导电滑环;34左导柱;35右导柱;36 弹黃;37右导槽。Label name among the figure: 1 cathode ray tube; 2 upper permanent magnets; 3 lower permanent magnets; 4 platforms; 5 upper stationary parts of sliding pairs; 6 upper sliding parts of sliding pairs; 7 connecting rods; 8 left guide grooves ; 9 crank; 10 motor; 11 stationary part of the lower sliding pair; 12 sliding part of the lower sliding pair; 13 handle; 14 upper guide rail; 15 lower guide rail; 16 left fluorescent board; 17 right fluorescent board; Base plate; 20 support frame; 21 left guide column; 22 left guide sleeve; 23 right guide column; 24 right guide sleeve; 25 left connecting rod; 26 right connecting rod; 27 transmission block; Drive permanent magnet; 31 rotating handle; 32 electromagnet; 33 conductive slip ring; 34 left guide post; 35 right guide post; 36 spring; 37 right guide groove.

具体实施方式detailed description

[°028]本发明实施例一如图1所示，该阴极射线磁追踪反应速度训练装置设有阴极射线管1、上永磁体2和下永磁体3;阴极射线管通过支架固定在平台4上，阴极射线呈水平状态；上永磁***于阴极射线管上方，阴极射线管上方设有上滑动副，上滑动副的静止部5通过支架连接在平台上，上永磁体与上滑动副的滑动部6连接为一体，上滑动副的滑动部的滑动方向为竖直方向，上滑动副的滑动部较接有连杆7,连杆铰接连接有曲柄9,曲柄连接有驱动机构，驱动机构可以为手摇式或手动弹簧蓄能式，本实施例的驱动机构为电机10;下永磁*** 于阴极射线管下方，阴极射线管下方设有下滑动副，下滑动副的静止部丨丨通过支架连接在平台上，下永磁体与下滑动副的滑动部I2连接为一体，下滑动副的滑动部的滑动方向为竖直方向，下滑动副的滑动部连接有手柄13 ;上永磁体和下永磁体同极相对，且垂直方向对齐。[°028] Embodiment one of the present invention is shown in Figure 1, and this cathode ray magnetic tracing reaction speed training device is provided with cathode ray tube 1, upper permanent magnet 2 and lower permanent magnet 3; The cathode ray tube is fixed on platform 4 by bracket On the top, the cathode ray is in a horizontal state; the upper permanent magnet is located above the cathode ray tube, and the upper sliding pair is arranged above the cathode ray tube, and the stationary part 5 of the upper sliding pair is connected on the platform through a bracket, and the sliding of the upper permanent magnet and the upper sliding pair Part 6 is connected as a whole, the sliding direction of the sliding part of the upper sliding pair is the vertical direction, the sliding part of the upper sliding pair is connected with the connecting rod 7, the connecting rod is hingedly connected with the crank 9, the crank is connected with the driving mechanism, and the driving mechanism can It is a manual or manual spring energy storage type. The driving mechanism of this embodiment is a motor 10; the lower permanent magnet is located below the cathode ray tube, and a lower sliding pair is arranged below the cathode ray tube, and the stationary part of the lower sliding pair passes through the bracket Connected on the platform, the lower permanent magnet is connected as a whole with the sliding part I2 of the lower sliding pair, the sliding direction of the sliding part of the lower sliding pair is the vertical direction, and the sliding part of the lower sliding pair is connected with a handle 13; the upper permanent magnet and the lower The permanent magnets face each other with the same poles and are vertically aligned.

[0029]为了便于调节，本实施例上滑动副的静止部通过上导轨14与支架相连，下滑动副的静止部通过下导轨15与支架相连，上导轨和下导轨的运动方向均为水平方向，可以水平调节使上永磁体、下永磁体和阴极射线在同一垂面上，当然实施时，该水平调节机构也可以设在阴极射线管上，或调节好后直接固定连接在支架上。In order to facilitate adjustment, the stationary part of the upper sliding pair in the present embodiment is connected with the support by the upper guide rail 14, and the stationary part of the lower sliding pair is connected with the support by the lower guide rail 15, and the direction of motion of the upper guide rail and the lower guide rail is the horizontal direction , can be adjusted horizontally so that the upper permanent magnet, the lower permanent magnet and the cathode ray are on the same vertical plane. Of course, during implementation, the horizontal adjustment mechanism can also be arranged on the cathode ray tube, or directly fixedly connected to the bracket after adjustment.

[0030]本发明使用时，阴极射线管通电产生电子束，上永磁体在驱动电机作用下往复运动，接近、远离阴极射线管，电子束受到洛伦兹力作用发生偏转波动，此时受训人员手持下永磁体随上永磁体的动作做出反应，使下永磁体对电子束施加一个与上永磁体相反方向的磁场，以平衡上永磁体对电子束的作用，使电子束趋于平直，如果训练中电子束变化幅度较大，说明受训人员的反应速度较慢，通过调节上永磁体运动速度可以适应不同难度等级的训练，驱动电机可设置几个档位或用调速变频电机。本装置训练不受场地制约，训练负荷小，可以提高反应速度和时机判断能力，作为实战以外的训练，效果显著，还可以用于儿童感觉统合的训练，训练器手眼协调能力。When the present invention uses, cathode ray tube energizes and produces electron beam, and upper permanent magnet reciprocates under the effect of driving motor, approaches, stays away from cathode ray tube, and electron beam is subject to Lorentz force effect and deflection fluctuation occurs, and trainees now Hold the lower permanent magnet to react with the action of the upper permanent magnet, so that the lower permanent magnet applies a magnetic field in the opposite direction to the upper permanent magnet to the electron beam, so as to balance the effect of the upper permanent magnet on the electron beam and make the electron beam tend to be straight , if the electron beam changes greatly during the training, it means that the trainee’s reaction speed is slow. By adjusting the movement speed of the upper permanent magnet, it can adapt to the training of different difficulty levels. The device training is not restricted by the venue, the training load is small, and can improve the reaction speed and timing judgment ability. As a training other than actual combat, the effect is remarkable. It can also be used for children's sensory integration training and hand-eye coordination ability of the trainer.

[0031] 进一步的，上永磁体、下永磁体是同一规格的永磁体。同一规格值得是形状、尺寸、磁感应强度都相同。这样便于得到方向相反的磁场。Further, upper permanent magnet, lower permanent magnet are the permanent magnets of same specification. The same specification is worth the same shape, size, and magnetic induction. This facilitates obtaining magnetic fields in opposite directions.

[0032] 本发明实施例二如图2至5所示，该阴极射线磁追踪反应速度训练装置，在阴极射线管内阴极射线左、右分别设置竖直的左荧光板ie和右荧光板17,阴极射线管内左、右荧光板分别固定连接在左基板18、右基板19,阴极射线管内设有与其壳***置相对固定的支撑架20，左基板通过配合的左导柱21、左导套22与支撑架连接，右基板通过配合的右导柱23、右导套24与支撑架连接，左基板、右基板上分别铰接有长度相同的左连杆25和右连杆26,左连杆和右连杆另一端靠近铰接在一传动块27上，传动块上设有螺纹，与该螺纹配合设有轴向位置固定的旋转驱动块28,旋转驱动块轴向外端靠近阴极射线管壳体处设有与旋转驱动块同轴旋转的导体片29，（相关领域技术人员应当知晓，导体片应当由非磁性材料制得，比如由铜制得，比如由铝制得，比如由锌制得，导体片29不宜选用铁、钴、镍材料。）对应导体片在阴极射线管壳体外设有旋转磁驱动机构;本实施例旋转磁驱动机构为一与导体片形状相同的驱动永磁体30，驱动永磁体连接有旋转柄31;与导体片位置相对的阴极射线管壳体设有向内凹陷，呈喇叭状，驱动永磁体放入喇叭状凹陷内，用旋转柄转动驱动永磁体,驱动永磁体隔着阴极射线管壳带动导体片旋转(根据楞次定律可知），导体片带动旋转驱动块使传动块轴向移动，传动块通过左连杆和右连杆带动左、右导套靠近或分离，从而调节左、右荧光板的间距，调到合适间距后移走驱动永磁体，避免其磁场对训练产生干扰，隔离传动密闭性好，左、右荧光板的间距稳定。本实施例左、右荧光板的设置，在电子束偏离较大时可以打在荧光板上，荧光板发出亮点，这样裁判就能更好地观察到，使评判更准确和公正，而且左、右荧光板间距可调，可以设置不同的训练难度。Embodiment two of the present invention as shown in Fig. 2 to 5, this cathode ray magnetic tracing reaction speed training device, cathode ray left and right in the cathode ray tube are respectively provided with vertical left fluorescent plate 1e and right fluorescent plate 17, The left and right fluorescent plates in the cathode ray tube are respectively fixedly connected to the left base plate 18 and the right base plate 19. The cathode ray tube is provided with a support frame 20 relatively fixed to its housing position, and the left base plate passes through the matching left guide post 21 and left guide sleeve 22 Be connected with bracing frame, right base plate is connected with bracing frame by right guide post 23, right guide sleeve 24 of cooperation, left connecting rod 25 and right connecting rod 26 with the same length are respectively hinged on left base plate, right base plate, left connecting rod and The other end of the right connecting rod is hinged close to a transmission block 27. The transmission block is provided with a screw thread, which is matched with a rotary drive block 28 with a fixed axial position. The axial outer end of the rotary drive block is close to the cathode ray tube casing. There is a conductor piece 29 coaxially rotating with the rotary drive block, (those skilled in the art should know that the conductor piece should be made of non-magnetic material, such as copper, such as aluminum, such as zinc , the conductor sheet 29 should not be selected from iron, cobalt, nickel materials.) The corresponding conductor sheet is provided with a rotating magnetic drive mechanism outside the cathode ray tube housing; the rotating magnetic drive mechanism in this embodiment is a driving permanent magnet 30 with the same shape as the conductor sheet, The driving permanent magnet is connected with a rotating handle 31; the cathode ray tube housing opposite to the conductor sheet is provided with an inward recess, which is in the shape of a horn, and the driving permanent magnet is placed in the horn-shaped recess, and the rotating handle is used to rotate the driving permanent magnet to drive the permanent magnet. The magnet drives the conductor sheet to rotate through the cathode ray tube shell (according to Lenz's law), the conductor sheet drives the rotating drive block to move the transmission block axially, and the drive block drives the left and right guide sleeves to approach or Separate, so as to adjust the distance between the left and right fluorescent boards, remove the driving permanent magnet after adjusting to a suitable distance, to avoid its magnetic field from interfering with training, the isolation transmission is good, and the distance between the left and right fluorescent boards is stable. The setting of the left and right fluorescent boards in this embodiment can hit the fluorescent boards when the electron beam deviates greatly, and the fluorescent boards emit bright spots, so that the judges can better observe and make the judgment more accurate and fair. The distance between the right fluorescent boards is adjustable, and different training difficulties can be set.

[0033]本发明为什么采用这样的调节方式呢？原因是:这样的调节方式不改变阴极射线管内部的体积。Why does the present invention adopt such adjustment mode? Reason is: such adjustment mode does not change the volume inside the cathode ray tube.

[0034]实施时实施例二中导体片为两片以上，以旋转驱动块轴线为轴周向均匀阵列分布，驱动永磁体数量和位置与导体片—对应，驱动磁力链接更稳定。Conductor sheet is more than two in the embodiment two during implementation, is that axis circumferential uniform array is distributed with rotating drive block axis, drives permanent magnet quantity and position and conductor sheet-corresponding, drives magnetic link more stable.

[0035]阴极射线管内阴极射线左、右分别设有竖直的左荧光板和右荧光板。之所以这样设置的原因是:通常人们采用磁感线大致竖直方向但是稍斜的磁场，这样导致电子束水平方向偏转。比如采用条形磁铁作为上永磁体和下永磁体。[0035] The left and right sides of the cathode ray tube are respectively provided with a vertical left fluorescent plate and a right fluorescent plate. The reason why it is set up like this is: usually people adopt the magnetic field that the magnetic induction line is roughly vertical but slightly oblique, which causes the electron beam to deflect in the horizontal direction. For example, bar magnets are used as the upper permanent magnet and the lower permanent magnet.

[0036] 相关领域技术人员应当知晓，不能采用匀强磁场。Those skilled in the art should know that uniform magnetic field cannot be used.

[0037]实施时实施例二中旋转磁驱动机构，还可为一与导体片形状相同的电磁铁，如图6 所示，电磁铁32连接有驱动电机，驱动电机驱动电磁铁的旋转轴线与旋转驱动块同轴，电磁铁线圈与驱动电机供电回路串联，电磁铁线圈通过导电滑环33与供电回路连接，用旋转的电磁铁驱动导体片调节左、右荧光板的间距，自动化便捷省力。实施时电磁铁线圈也可单独通过一导电滑环连接电源，可以自行切断电源。Rotating magnetic drive mechanism in embodiment two during implementation can also be an electromagnet identical with conductor sheet shape, as shown in Figure 6, electromagnet 32 is connected with driving motor, and the axis of rotation of driving motor drives electromagnet and The rotating drive block is coaxial, the electromagnet coil is connected in series with the drive motor power supply circuit, and the electromagnet coil is connected to the power supply circuit through a conductive slip ring 33, and the rotating electromagnet is used to drive the conductor piece to adjust the distance between the left and right fluorescent plates, which is convenient and labor-saving. During implementation, the electromagnet coil can also be connected to the power supply through a conductive slip ring alone, and the power supply can be cut off automatically.

[0038]电磁铁32采用无铁芯的电磁铁，为什么要采用无铁芯的电磁铁呢？因为铁芯往往有剩磁，剩磁会对电子束的运动造成千扰，很难让电子束仅仅在上永磁体、下永磁体的作用下保持平衡。同理，绕制电磁铁的导线不能选用铁、钴、镍制得。Electromagnet 32 adopts the electromagnet without iron core, why will adopt the electromagnet without iron core? Because the iron core often has residual magnetism, the residual magnetism will disturb the movement of the electron beam, and it is difficult to keep the electron beam in balance only under the action of the upper permanent magnet and the lower permanent magnet. In the same way, the wires of the wound electromagnets cannot be made of iron, cobalt, or nickel.

[0039]电磁铁线圈与驱动电机供电回路串联，其原因是：电磁铁通电要产生磁场，这个磁场对电子束的运动产生干扰，对使用本发明造成不良影响，串联的好处就是不转动的时候，电磁铁不产生磁场，对电子束的运动没有影响。Electromagnet coil is connected in series with driving motor power supply circuit, and its reason is: electromagnet energization will produce magnetic field, and this magnetic field interferes with the motion of electron beam, causes adverse effect to using the present invention, and the benefit of series connection is exactly when not rotating , The electromagnet does not generate a magnetic field and has no effect on the movement of the electron beam.

[0040]电磁铁线圈通过导电滑环33与供电回路连接，其原因是：电磁铁线圈与驱动电机供电回路串联，且电磁铁要旋转，这样设计有一个技术问题:不方便给电磁铁供电。电磁铁线圈通过导电滑环33与供电回路连接，就可以解决这个问题。Electromagnet coil is connected with power supply circuit by conductive slip ring 33, and its reason is: electromagnet coil is connected with driving motor power supply circuit, and electromagnet will rotate, and design has a technical problem like this: it is inconvenient to supply power to electromagnet. The electromagnet coil is connected with the power supply circuit through the conductive slip ring 33, which can solve this problem.

[0041] 实施例二中左、右导柱分别与左、右荧光板垂直，导柱为圆柱形，实施时该导向机构也可以为倾斜式非圆柱形，如实施例三图7所示，左导柱34上端、右导柱35下端分别向同一方向倾斜，左导柱34与右导柱35截面呈燕尾型，分别配合在左导槽8、右导槽37内，同样可以实现左、右荧光板间距的调节。 _In embodiment two, left and right guide pillars are perpendicular to left and right fluorescent plates respectively, and guide pillars are cylindrical, and this guide mechanism also can be inclined non-cylindrical during implementation, as shown in Fig. 7 of embodiment three, The upper end of the left guide post 34 and the lower end of the right guide post 35 are inclined to the same direction respectively. Adjustment of the distance between the right phosphor plates. _

[0042] 本发明实施时，上永磁体通过一弹簧36与上滑动副的滑动部连接，如图8所示，利用弹簧增加运动复杂性，进一步调高训练难度。During the implementation of the present invention, the upper permanent magnet is connected with the sliding portion of the upper sliding pair by a spring 36, as shown in Figure 8, utilizes the spring to increase the complexity of motion, and further adjusts the difficulty of training.

[0043] 综上所述仅为本发明较佳实施例，凡依本申请所做的等效修饰和现有技术添加均视为本发明技术范畴。In summary, the above is only a preferred embodiment of the present invention, and all equivalent modifications and prior art additions done according to the application are all considered as the technical category of the present invention.

Claims

1.一种阴极射线磁追踪反应速度训练装置，其特征在于包括阴极射线管、上永磁体和下永磁体;阴极射线管通过支架固定在平台上，阴极射线呈水平状态;上永磁***于阴极射线管上方，阴极射线管上方设有上滑动副，上滑动副的静止部通过支架连接在平台上，上永磁体与上滑动副的滑动部连接为一体，上滑动副的滑动部的滑动方向为竖直方向，上滑动副的滑动部铰接有连杆，连杆铰接连接有曲柄，曲柄连接有驱动机构；下永磁***于阴极射线管下方，阴极射线管下方设有下滑动副，下滑动副的静止部通过支架连接在平台上，下永磁体与下滑动副的滑动部连接为一体，下滑动副的滑动部的滑动方向为竖直方向，下滑动副的滑动部连接有手柄;上永磁体和下永磁体同极相对，且垂直方向对齐，所述阴极射线管内阴极射线左、右分别设有竖直的左荧光板和右荧光板，所述阴极射线管内左、右荧光板分别固定连接有左基板、右基板，阴极射线管内设有与其壳***置相对固定的支撑架，左基板通过配合的左导柱、左导套与支撑架连接，右基板通过配合的右导柱、右导套与支撑架连接，左基板、右基板上分别铰接有长度相同的左连杆和右连杆，左连杆和右连杆另一端靠近铰接在一传动块上，传动块上设有螺纹，与该螺纹配合设有轴向位置固定的旋转驱动块，旋转驱动块轴向外端靠近阴极射线管壳体处设有与旋转驱动块同轴旋转的导体片，对应导体片在阴极射线管壳体外设有旋转磁驱动机构，所述旋转磁驱动机构为一与导体片形状相同的电磁铁，电磁铁连接有驱动电机，驱动电机驱动电磁铁的旋转轴线与旋转驱动块同轴，电磁铁线圈与驱动电机供电回路串联，电磁铁线圈通过导电滑环与供电回路连接。1. A cathode ray magnetic tracing reaction speed training device is characterized in that comprising a cathode ray tube, an upper permanent magnet and a lower permanent magnet; the cathode ray tube is fixed on the platform by a support, and the cathode ray is in a horizontal state; the upper permanent magnet is located at the cathode Above the ray tube, above the cathode ray tube is provided with an upper sliding pair, the stationary part of the upper sliding pair is connected on the platform through a bracket, the upper permanent magnet is connected with the sliding part of the upper sliding pair as a whole, the sliding direction of the sliding part of the upper sliding pair In the vertical direction, the sliding part of the upper sliding pair is hinged with a connecting rod, the connecting rod is hingedly connected with a crank, and the crank is connected with a driving mechanism; the lower permanent magnet is located under the cathode ray tube, and the lower sliding pair is arranged under the cathode ray tube. The stationary part of the pair is connected on the platform through a bracket, the lower permanent magnet is connected with the sliding part of the lower sliding pair as a whole, the sliding direction of the sliding part of the lower sliding pair is the vertical direction, and the sliding part of the lower sliding pair is connected with a handle; The permanent magnet and the lower permanent magnet are opposite to each other with the same poles, and are vertically aligned. The left and right sides of the cathode ray in the cathode ray tube are respectively provided with a vertical left fluorescent plate and a right fluorescent plate, and the left and right fluorescent plates in the cathode ray tube are respectively The left base plate and the right base plate are fixedly connected, and a support frame relatively fixed to the position of the cathode ray tube is arranged in the cathode ray tube. The right guide sleeve is connected with the support frame, the left base plate and the right base plate are respectively hinged with a left connecting rod and a right connecting rod with the same length, and the other ends of the left connecting rod and the right connecting rod are hinged close to a transmission block, and the transmission block is provided with A screw thread, which is matched with a rotary drive block with a fixed axial position, and a conductor sheet coaxially rotating with the rotary drive block at the axial outer end of the rotary drive block close to the cathode ray tube casing, corresponding to the conductor sheet A rotating magnetic driving mechanism is arranged outside the tube shell, and the rotating magnetic driving mechanism is an electromagnet having the same shape as the conductor sheet. The iron coil is connected in series with the power supply circuit of the driving motor, and the electromagnet coil is connected with the power supply circuit through a conductive slip ring.