CN111249720B - Handle data measuring device - Google Patents

Abstract

The invention discloses a handle data measuring device, which comprises a simulation handle, a support arm and a simulation trigger key, wherein the simulation handle is provided with an installation cavity and an installation port communicated with the installation cavity; the first end of the support arm is rotatably connected with the mounting cavity, and the second end of the support arm extends out of the mounting opening; the simulation trigger key is arranged at the second end of the support arm; and at least one measuring mark corresponding to the motion path of the simulated trigger key is also arranged on the simulated handle. The technical scheme of the invention can improve the accuracy of measuring the handle equipment.

Description

Handle data measuring device

Technical Field

The invention relates to the technical field of measuring instruments, in particular to a handle data measuring device.

Background

In the existing handle devices, such as game handles or remote control handles, users usually customize the handle devices according to the sizes of hands in order to improve the comfort of holding the handle devices and reduce finger fatigue, and currently, devices such as a ruler, a vernier caliper, a protractor and the like are generally used for measurement when the key positions on the handle devices are customized, but the measurement errors of the universal measurement tools are large, the universal measurement tools are not easy to operate, even some sizes cannot be measured, and the measurement accuracy is greatly limited.

Disclosure of Invention

The invention mainly aims to provide a handle data measuring device which aims to improve the accuracy of measuring handle equipment.

In order to achieve the above object, the present invention provides a handle data measurement device, comprising:

comprising the following steps:

the simulation handle is provided with an installation cavity and an installation port communicated with the installation cavity;

the first end of the support arm is rotatably connected with the mounting cavity, and the second end of the support arm extends out of the mounting opening; a kind of electronic device with high-pressure air-conditioning system;

the simulation trigger key is arranged at the second end of the support arm;

and at least one measuring mark corresponding to the motion path of the simulated trigger key is also arranged on the simulated handle.

Optionally, the simulation handle is further provided with a guide arc groove penetrating through the cavity wall of the installation cavity, the support arm is provided with a sliding shaft extending out of the guide arc groove, the outer end of the sliding shaft is provided with a pointer, and the pointer faces one measurement mark.

Optionally, the rotation angle of the support arm is adjusted to be in a range of 0-70 degrees.

Optionally, the simulation handle includes main part section and gripping section, the installation mouth is located the main part section deviate from the one side of gripping section, the gripping section disposes a plurality ofly, the difference the shape and/or the size of gripping section are different, the main part section can dismantle and connect in arbitrary the gripping section.

Optionally, one of the main body section and the holding section is provided with a connecting hole, and the other is provided with a connecting part which is in interference fit with the connecting hole; or alternatively, the process may be performed,

one of the main body section and the holding section is provided with a connecting hole, the other one of the main body section and the holding section is provided with a connecting part, the connecting part is inserted into the connecting hole, the handle data measuring device further comprises a limiting part, and the limiting part is connected with the hole wall of the connecting hole and the connecting part.

Optionally, the handle data measurement device further comprises a plurality of analog control keys; the simulation handle is provided with a plurality of adjustment positions which are arranged in an array, and any simulation control key is detachably arranged at any adjustment position.

Optionally, the adjusting position includes at least two first adjusting holes, and the analog control key is provided with a first adjusting plug-in connection part corresponding to each first adjusting hole.

Optionally, the handle data measurement device further comprises a simulation main body, two simulation handles are arranged, and the two simulation handles are respectively connected to two opposite sides of the simulation main body.

Optionally, the simulation main part is equipped with first location portion and first regulation portion, the simulation handle is equipped with second location portion and second regulation portion, first location portion with second location portion can dismantle the connection, second regulation portion along two the direction of arranging of simulation handle with first regulation portion is connected.

Optionally, the first positioning portion includes the locating hole, the first regulation portion includes a plurality of second regulation holes, a plurality of the second regulation holes with the center of locating hole is the centre of a circle arranges into the arc, the second positioning portion includes location grafting portion, the second regulation portion includes the second and adjusts grafting portion, location grafting portion inserts and locates the locating hole, the second is adjusted grafting portion and is pegged graft in arbitrary second regulation hole.

Optionally, any two adjacent second adjusting holes are communicated with each other.

Optionally, the included angle between the two analog handles is adjusted to be 20-60 degrees.

According to the technical scheme, the mounting cavity and the mounting port communicated with the mounting cavity are formed in the simulation handle, so that the first end of the support arm can be rotatably connected into the mounting cavity, the second end of the support arm extends out of the mounting port, the simulation trigger key is arranged at the second end of the support arm and is positioned outside the mounting cavity, and the simulation handle is further provided with a measurement mark corresponding to the movement path of the simulation trigger key. When the measured person measures through the handle data measuring device, the measured person holds the simulated handle, the corresponding finger is placed on the simulated trigger key, and the position of the simulated trigger key can be adjusted by rotating the simulated trigger key, so that when the simulated trigger key is in a state which is more suitable for the measured person, the actual state of the measuring mark corresponding to the simulated trigger key or the support arm at the moment can be checked and obtained. The measuring process is simple, convenient and quick, and the measuring efficiency is improved. Because the measurement mark can be preset, the accuracy of the measurement mark is easy to be ensured, and measurement devices such as a protractor and the like are not needed to measure in the measurement process, so that higher measurement accuracy can be ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of an embodiment of a handle data measuring device according to the present invention;

FIG. 2 is a schematic view of the simulated handle of FIG. 1 with simulated control keys mounted thereon;

FIG. 3 is a schematic diagram of an analog control key of FIG. 2;

FIG. 4 is a schematic diagram of another analog control key of FIG. 2;

FIG. 5 is a schematic view of the structure of a simulated handle and a simulated body in an embodiment of the handle data measuring device of the present invention;

FIG. 6 is an exploded schematic view of the simulated handle and simulated body of FIG. 5;

fig. 7 is an enlarged view at a in fig. 6.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present invention, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" as it appears throughout is meant to include three side-by-side schemes, for example, "a and/or B", including a scheme, or B scheme, or a scheme that is satisfied by both a and B. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The invention provides a handle data measuring device which can be used for measuring related parameters of handle equipment structures such as a game handle or a remote control handle in a simulation manner.

In the embodiment of the present invention, please refer to fig. 1 in combination, the handle data measuring device includes a simulation handle 20, a support arm 50 and a simulation trigger key 40, the simulation handle 20 is provided with a mounting cavity 21 and a mounting opening 221 communicating with the mounting cavity 21, a first end of the support arm 50 is rotatably connected to the mounting cavity 21, a second end of the support arm 50 extends out of the mounting opening 221, the simulation trigger key 40 is provided at the second end of the support arm 50, and at least one measuring mark 226 corresponding to a movement path of the simulation trigger key 40 is further provided on the simulation handle 20.

In some embodiments, the measurement indicia 226 may be disposed on an outer surface of the simulated handle 20 or at an end of the simulated handle 20 remote from the simulated trigger key 40. The measurement indicia 226 may be an angle scale, a distance scale, or other positioning indicia that corresponds one-to-one to the path of movement of the simulated trigger key 40. In addition, the measurement mark 223 may be provided in a single or a plurality of stages, for example, in a form of multistage positioning matching with the multistage positioning groove.

The simulated trigger key 40 is used to simulate the trigger key position of the handle device in use, and the simulated trigger key 40 is located at the end of the simulated handle 20 so that the subject's finger can be placed on the simulated trigger key 40 while the subject is holding the simulated handle 20. In one embodiment, the simulated handle 20 comprises a main body section 22 and a holding section 23 which are connected, and the mounting opening 221 is formed on one side of the main body section 22 away from the holding section 23, and a subject holds the holding section 23 during measurement. The second end of the arm 50 extends out of the mounting opening 221 in a direction away from the grip section 23. The extension direction of the rotation axis of the arm 50 is approximately perpendicular to the arrangement direction of the main body section 22 and the holding section 23, and the rotation plane of the arm 50 is approximately parallel to the arrangement direction of the main body section 22 and the holding section 23.

The indication part may be provided on the analog trigger key 40 or the arm 50, and the indication part may be any part or mark on the analog trigger key 40 or any part or mark on the arm 50. And a reference portion is preselected on the analog handle 20, which may be a marked line on the analog handle 20, or a marked protrusion, or a marked groove, or the like. The measurement mark 226 is set to extend along the direction of the rotating path of the indication part, and the angle value corresponding to the measurement mark 226 can be preset, and the preset angle value refers to the angle of the support arm 50 or the simulation trigger key 40 relative to the reference part on the simulation handle 20 when the indication part points to any scale. Obtaining data of the relative position of the reference portion on the simulated handle 20 and data of the angle of the arm 50/simulated trigger key 40 (arm 50 or simulated trigger key 40) relative to the reference portion can correspondingly set the position of the trigger key on the handle device relative to the handle on the handle device. When the measured person measures through the handle data measuring device, the measured person holds the simulated handle 20, places the corresponding finger on the simulated trigger key 40, and can adjust the position of the simulated trigger key 40 by rotating the simulated trigger key 40, so that when the simulated trigger key 40 is in a state more suitable for the measured person, the numerical value of the corresponding measuring mark 226 of the indicating part at the moment can be checked and obtained.

According to the technical scheme of the invention, the mounting cavity 21 and the mounting opening 221 communicated with the mounting cavity 21 are arranged on the simulation handle 20, so that the first end of the support arm 50 can be rotatably connected in the mounting cavity 21, the second end of the support arm 50 extends out of the mounting opening 221, the simulation trigger key 40 is arranged at the second end of the support arm 50 and is positioned outside the mounting cavity 21, and the simulation handle 20 is also provided with the measurement mark 226 corresponding to the movement path of the simulation trigger key 40. When the measured person measures the measured person through the handle data measuring device, the measured person holds the simulated handle 20, places the corresponding finger on the simulated trigger key 40, and can adjust the position of the simulated trigger key 40 by rotating the simulated trigger key 40, so that when the simulated trigger key 40 is in a state suitable for the measured person, the actual state of the measured mark 226 corresponding to the simulated trigger key 40 or the support arm 50 at the moment can be checked and obtained. The measuring process is simple, convenient and quick, and the measuring efficiency is improved. Because the measurement mark 226 can be preset, the accuracy of the measurement mark 226 is easy to be ensured, and measurement by measuring devices such as a protractor and the like are not needed in the measurement process, so that higher measurement accuracy can be ensured.

In one embodiment, the simulation handle 20 is further provided with a guiding arc groove 225 penetrating through the wall of the mounting cavity 21, the support arm 50 is provided with a sliding shaft 51 (please refer to fig. 1 and 7) extending out of the guiding arc groove 225, the outer end of the sliding shaft 51 is provided with a pointer 52, and the pointer 52 is arranged towards a measuring mark 226. Specifically, the pointer 52 is the indication portion, the extending direction of the guiding arc groove 225 is identical to the rotating direction of the arm 50, the radian of the guiding arc groove 225 is substantially the same as the rotating radian of the sliding shaft 51, and the sliding shaft 51 is slidably connected in the guiding arc groove 225. The measuring mark 226 is arranged beside the guiding arc groove 225, and the scale direction of the measuring mark 226 is consistent with the extending direction of the guiding arc groove 225, so that the pointer 52 can accurately and correspondingly point to the measuring mark 226 when the pointer 52 moves along with the support arm 50. And the pointer 52 points to the measuring mark 226, so that the relative position data of the simulated trigger key 40 on the simulated handle 20 can be conveniently observed, and the measuring efficiency can be improved. When the sliding shaft 51 is slidably connected to the guide arc groove 225, the support arm 50 can be guided and limited through the guide arc groove 225 during rotation, the contact area between the support arm 50 and the simulation handle 20 is increased, and the rotation stability of the support arm 50 can be ensured. In order to further improve the rotation stability of the support arm 50, in one embodiment, the two opposite cavity walls of the mounting cavity 21 are provided with guiding sliding grooves, two ends of the sliding shaft 51 are respectively arranged on two opposite sides of the support arm 50, and two ends of the sliding shaft 51 are respectively and slidably connected to the guiding arc grooves 225, so that the two opposite sides of the support arm 50 are uniformly stressed, which is beneficial to improving the rotation stability of the support arm 50.

In one embodiment, the angular adjustment of the arm 50 is in the range of 0 to 70. Specifically, the maximum rotation angle range of the arm 50 is 70 °, that is, when the arm 50 rotates to the limit positions at both ends of the guide arc groove 225, the angle between the two limit positions of the arm 50 is greater than or equal to 0 °, and is less than or equal to 70 °. The larger the rotation angle adjustment range of the support arm 50 is, the larger the adjustment range of the analog control key 30 is, so that the measurement of different testees is facilitated. If the rotation angle adjustment range of the support arm 50 is set too large, on the one hand, the length of the guide arc groove 225 is increased, and the processing cost is increased, on the other hand, when the support arm 50 rotates to the limit positions at the two ends of the guide arc groove 225, the rotation offset of the analog control key 30 is too large, and the position of the analog control key 30 exceeds the operable range of the testee, so that the part exceeding the operable range of the testee is wasted. And when the rotation angle of the support arm 50 is adjusted to be 0-70 degrees, the measurement requirements of different testers can be met, the length of the guide arc groove 225 can be reduced, and the processing cost is reduced.

In one embodiment, the grip section 23 is configured with a plurality of grip sections 23 having different shapes and/or sizes, and the body section 22 is detachably connected to any grip section 23. The mounting cavity 21 is provided in the body section 22. It will be appreciated that the gripping requirements for the simulated handle 20 will also vary when the type of subject's hand and the size of the hand are different. The plurality of grip sections 23 having different shapes, or the plurality of grip sections 23 having different sizes, or the plurality of grip sections 23 having different shapes and sizes are provided in advance, and the grip sections 23 are detachably connected to the main body section 22. The holding section 23 with proper shape and/or size can be conveniently selected by the testee, so that the shape and size of the handle required by the testee can be conveniently measured, the testee can intuitively feel the complete handle structure, the holding experience of the physical simulation of the testee can be provided, and the data can be measured and collected in a more accurate and intuitive mode.

There are various ways to connect the main body section 22 and the holding section 23, for example, in one embodiment, one of the main body section 22 and the holding section 23 is provided with a connecting hole (not shown), and the other is provided with a connecting portion (not shown) which is in interference fit with the connecting hole. Specifically, the body section 22 may be provided with a connection hole, the grip section 23 may be provided with a connection portion, or the grip section 23 may be provided with a connection hole, and the body section 22 may be provided with a connection portion. When the connecting part is in interference fit with the connecting hole, the connecting part is tightly matched with the connecting hole, and the connecting part is limited to be separated from the connecting hole through friction force between the connecting part and the hole wall of the connecting hole. The structure is simple, and the disassembly and the assembly are convenient.

In another embodiment, one of the main body section 22 and the holding section 23 is provided with a connecting hole, the other is provided with a connecting part, the connecting part is inserted into the connecting hole, and the handle data measuring device further comprises a limiting piece (not shown in the figure), wherein the limiting piece is connected to the hole wall of the connecting hole and the connecting part. Specifically, the hole wall of the connecting hole is provided with a yielding hole (not shown in the figure), the connecting part is provided with a limiting hole, and when the connecting part is inserted into the connecting hole, the yielding hole and the limiting hole can correspond to each other, so that the limiting piece can be inserted into the limiting hole from the yielding hole, the connecting part is limited to move far along the axial direction of the connecting hole, and the connecting part is prevented from being separated from the connecting hole. Therefore, the limit is firmer, so that the connection between the main body section 22 and the holding section 23 is more stable, and the measurement and the use are convenient. Wherein, the limiting piece can be a pin or a screw, etc.

Referring to fig. 2 to 4 in combination, in one embodiment, the handle data measurement device further includes a plurality of analog control keys 30; the simulation handle 20 is provided with a plurality of adjustment positions which are arranged in an array, and any simulation control key 30 can be detachably arranged at any adjustment position. So be equivalent to arbitrary one analog control key 30 all can install the optional position that has the regulation hole on analog handle 20, can conveniently change the position and/or the angle of analog control key 30 on analog handle 20, and through setting up not unidimensional analog control key 30, still conveniently change not unidimensional analog control key 30 to obtain the button overall arrangement that is comparatively fit for the testee, make test process more convenient. The analog control keys 30 may be push buttons, touch buttons, control sticks, and the like. In addition, the plurality of adjustment positions can be uniformly distributed in an array, namely, the distances between any two adjacent adjustment positions are equal along the same distribution direction of the plurality of adjustment positions, or the distances between any two adjacent adjustment positions are equal along the random distribution direction of the plurality of adjustment positions.

In one embodiment, the adjusting position includes at least two first adjusting holes 224, and the analog control key 30 is provided with a first adjusting plug portion 31 corresponding to each first adjusting hole 224. It will be appreciated that. When the adjusting position includes two first adjusting holes 224, the analog control key 30 is provided with two first adjusting plug-in parts 31, and the two first adjusting plug-in parts 31 are correspondingly plugged in the two first adjusting holes 224 respectively. When the adjusting positions include three first adjusting holes 224, the analog control key 30 is provided with three first adjusting plug-in parts 31, and the three first adjusting plug-in parts 31 are respectively plugged in correspondence to the three first adjusting holes 224, where the three first adjusting holes 224 may be arranged in an equilateral triangle, or arranged randomly, or the like. The adjustment bits may also include four or five first adjustment holes 224, and so on. When the at least two first adjusting plug-in parts 31 are correspondingly plugged in the two first adjusting holes 224 respectively, the analog control key 30 can be conveniently fixed, the analog control key 30 can be limited to rotate on an adjusting position, and the connection position of the analog control key 30 and the analog handle 20 is increased, so that the analog control key 30 is more stable to install and is not easy to fall. Of course, in other embodiments, the adjustment position may be provided as a first adjustment aperture 224. Alternatively, the adjustment position may be a protrusion, and the analog control key 30 is provided with a groove or the like corresponding to the protrusion.

Referring to fig. 5 to 7 in combination, in one embodiment, the handle data measurement device further includes a simulation body 10, two simulation handles 20 are provided, and the two simulation handles 20 are respectively connected to two opposite sides of the simulation body 10. Specifically, the main body section 22 is connected with the simulation main body 10, and by providing two simulation handles 20, data of the simulation trigger keys 40 on the two simulation handles 20 can be conveniently and simultaneously measured, which is beneficial to improving the measurement efficiency. And when two simulation handles 20 are arranged, the testee can feel the complete handle structure intuitively, the physical simulation holding experience of the testee can be provided, and the data measurement and collection can be performed in a more accurate and intuitive mode.

Further, in an embodiment, the simulation main body 10 is provided with a first positioning portion and a first adjusting portion, the simulation handle 20 is provided with a second positioning portion and a second adjusting portion, the first positioning portion is detachably connected with the second positioning portion, and the second adjusting portion is movably connected with the first adjusting portion along the arrangement direction of the two simulation handles 20, so that an included angle between the two simulation handles 20 is adjustable. Namely, the simulation handles 20 are detachably connected with the simulation body 10, and the included angle between the two simulation handles 20 can be adjusted by changing the connection position of the second adjusting part and the first adjusting part.

The first positioning portion, the first adjusting portion, the second positioning portion and the second adjusting portion have various structures, for example, in this embodiment, the first positioning portion includes a positioning hole 11, the first adjusting portion includes a plurality of second adjusting holes 12, and the plurality of second adjusting holes 12 are arranged in an arc shape with a center of the positioning hole 11 as a center of a circle. The second positioning part comprises a positioning inserting part 222, the second adjusting part comprises a second adjusting inserting part 223, the positioning inserting part 222 is inserted into the positioning hole 11, and the second adjusting inserting part 223 is inserted into any second adjusting hole 12. Wherein the number of the plurality of second adjustment holes 12 may be one, two, three, four, five, six or more, etc. Of course, in other embodiments, the first positioning portion may include the positioning hole 11, the first adjusting portion includes a plurality of second adjusting holes 12, and the plurality of second adjusting holes 12 are arranged in an arc shape with the center of the positioning hole 11 as a center. The second positioning portion includes a positioning insertion portion 222, the second adjusting portion includes a second adjusting insertion portion 223, the positioning insertion portion 222 is inserted into the positioning hole 11, and the second adjusting insertion portion 223 is inserted into any second adjusting hole 12.

The centers of the second adjusting holes 12 are located on an arc line taking the center of the positioning hole 11 as the center of a circle, namely, the linear distances between any two second adjusting holes 12 and the positioning hole 11 are equal, and the positioning holes 11 are taken as the centers between any two adjacent second adjusting holes 12 to form an included angle, so that when the positioning inserting connection part 222 is inserted into the positioning hole 11, the second adjusting inserting connection part 223 can be inserted into any one second adjusting hole 12. By inserting the second adjustment insertion portion 223 into the different second adjustment hole 12, the position of the dummy handle 20 on the dummy body 10 can be adjusted by rotating the dummy handle 20 about the positioning insertion portion 222 as an axis.

When the plurality of second adjustment holes 12 are provided, data corresponding to each second adjustment hole 12 on the simulation body 10 may be preset, and the data acquisition manner includes, but is not limited to, for example, setting a reference straight line passing through the center of the positioning hole 11 and perpendicular to the axis of the positioning hole 11 on the simulation body 10, defining a connection line between the second adjustment holes 12 and the positioning hole 11 as a connection straight line, and presetting an included angle between the connection straight line and the reference straight line when the second adjustment holes 12 are provided. Namely, only by confirming the second adjusting hole 12 inserted into the second adjusting insertion part 223, the included angle between the connecting straight line of the second adjusting hole 12 and the reference straight line can be confirmed, and the position data of the simulation handle 20 corresponding to the simulation main body 10 can be obtained, so that the handle structure of the corresponding part can be set for the testee according to the data. Of course, when selecting the reference, the reference may be selected at a middle or side position of the simulation body 10, and so on.

During measurement, the second adjusting insertion part 223 can be inserted into one of the second adjusting holes 12 first, and then the second adjusting insertion part 223 is sequentially moved towards the adjacent second adjusting holes 12 according to the holding feedback of the testee until the testee holds the analog handle 20 in a more comfortable holding state, and the second adjusting holes 12 which are inserted into the second adjusting insertion part 223 at the moment can be recorded, so that the angle position data of the handle required by the testee can be obtained.

Wherein, the adjustable range of the simulation handle 20 can be set according to the number of the second adjusting holes 12, for example, when the distance between the second adjusting holes 12 and the positioning holes 11 is constant and the distance between any two adjacent second adjusting holes 12 is constant, the adjustable angle range of the simulation handle 20 on the simulation body 10 can be increased by increasing the number of the second adjusting holes 12. For example, when the distance between the second adjusting holes 12 and the positioning holes 11 is unchanged and the number of the second adjusting holes 12 is unchanged, the distance between two adjacent second adjusting holes 12 can be set smaller, so that the value of the included angle between two adjacent second adjusting holes 12 with the positioning holes 11 as the center can be reduced, that is, when the second adjusting plug part 223 moves from one of the second adjusting holes 12 to the adjacent second adjusting hole 12, the rotation angle of the analog handle 20 is smaller, and thus the adjusting precision of the analog handle 20 can be improved. Further, if the distance between the second adjustment hole 12 and the positioning hole 11 is set to be large, it is understood that the longer the distance from the positioning hole 11, the longer the arc edge of the fan shape is in the range of the fan shape centering on the positioning hole 11. So that a greater number of second adjustment holes 12 can be provided while the distance between adjacent two second adjustment holes 12 remains unchanged. But also can reduce the included angle value between two adjacent second adjusting holes 12, and can improve the adjusting precision of the simulation handle 20.

When the plurality of second adjusting holes 12 are provided, the data corresponding to each second adjusting hole 12 can be preset, so that when the measured data is measured on the testee, the position data of the simulation handle 20 corresponding to the simulation main body 10 can be obtained only by confirming the second adjusting holes 12 which are spliced with the second adjusting splicing parts 223. Compared with the position of the simulation handle 20 measured by measuring tools such as a measuring ruler, a protractor and the like, the position data of the positioning hole 11 and the plurality of second adjusting holes 12 are easy to determine, the setting precision is high, and the measuring precision can be improved. In addition, during measurement, the second adjusting insertion part 223 is inserted into the second adjusting hole 12 to be fixed, so that the condition that the simulation handle 20 shakes can be avoided, and the accuracy of measurement is guaranteed. In addition, since the measuring instrument is not required to measure the position data of the simulation handle 20 and the simulation body 10, it is advantageous to improve the measuring efficiency. In addition, since the simulation body 10 is detachably connected to the simulation handle 20, the simulation handle 20 can be detached to perform measurement independently when measuring data of the trigger key alone.

In one embodiment, the angle between the two simulated handles 20 is adjusted in the range of 20 to 60. Specifically, a set of second adjusting holes 12 is provided on the simulation body 10 corresponding to each simulation handle 20, that is, a set of second adjusting holes 12 on the simulation body 10 corresponding to one of the simulation handles 20, and a set of second adjusting holes 12 on the simulation body 10 corresponding to another simulation handle 20. By arranging two simulation handles 20, the data of the two handles can be conveniently and simultaneously measured, and the measurement efficiency is improved. And when two simulation handles 20 are arranged, the testee can feel the complete handle structure intuitively, the physical simulation holding experience of the testee can be provided, and the data measurement and collection can be performed in a more accurate and intuitive mode.

When the included angle between the two analog handles 20 is 20 °, the second adjusting insertion parts 223 on the two analog handles 20 are correspondingly inserted into the two second adjusting holes 12 close to each other in the two groups of second adjusting holes 12, and when the included angle between the two analog handles 20 is 60 °, the second adjusting insertion parts 223 on the two analog handles 20 are correspondingly inserted into the two second adjusting holes 12 far away from each other in the two groups of second adjusting holes 12. Although the hand shape and hand size of different subjects are different, the phase difference is not excessive. If the adjusting range of the included angle between the two analog handles 20 is too large, on one hand, the number of the second adjusting holes 12 is increased, so that the processing cost is increased, and on the other hand, when the included angle between the two handles of the handle device is too large, the operation of a user is very inconvenient. Therefore, when the included angle between the two simulation handles 20 is adjusted to be 20-60 degrees, the measurement requirements of different testees can be met, the number of the second adjusting holes 12 can be reduced, and the processing cost is reduced.

In one embodiment, any two adjacent second adjustment holes 12 are in communication with each other. Specifically, the vertical distance between the axes of the two adjacent second adjustment holes 12 is smaller than the diameter of the second adjustment hole 12, which is equivalent to reducing the distance between the two adjacent second adjustment holes 12, so that the arrangement of the plurality of second adjustment holes 12 is more compact, and the value of the included angle between the two adjacent second adjustment holes 12 with the positioning hole 11 as the center, that is, when the second adjustment plug-in connection 223 moves from one of the second adjustment holes 12 into the adjacent second adjustment hole 12, the rotation angle of the simulation handle 20 is smaller, and thus the adjustment precision of the simulation handle 20 can be improved. In an embodiment, the vertical distance between the axes of the two adjacent second adjusting holes 12 is larger than the radius of the second adjusting hole 12, i.e. the width of the connection between the two adjacent second adjusting holes 12 is smaller than the diameter of the second adjusting insertion portion 223, so that the connection between the two adjacent second adjusting holes 12 can prevent the second adjusting insertion portion 223 from sliding between the two adjacent second adjusting holes 12, i.e. prevent the second adjusting insertion portion 223 from sliding from the second adjusting hole 12 into the adjacent second adjusting hole 12.

In some embodiments, the first positioning portion and the second positioning portion may also adopt a magnetic attraction structure or a sliding rail structure.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims (11)

1. A handle data measurement device, comprising:

the simulation handle is provided with an installation cavity and an installation port communicated with the installation cavity;

the first end of the support arm is rotatably connected with the mounting cavity, and the second end of the support arm extends out of the mounting opening; a kind of electronic device with high-pressure air-conditioning system;

the simulation trigger key is arranged at the second end of the support arm;

the simulated handle is also provided with at least one measuring mark corresponding to the motion path of the simulated trigger key;

the simulation handle is further provided with a guide arc groove penetrating through the cavity wall of the installation cavity, the support arm is provided with a sliding shaft extending out of the guide arc groove, the outer end of the sliding shaft is provided with a pointer, and the pointer faces one measuring mark.

2. The handle data measuring device of claim 1, wherein the angular adjustment of the arm is in the range of 0 ° to 70 °.

3. The handle data measurement device of claim 1, wherein the simulated handle comprises a body section and a grip section, the mounting port being provided on a side of the body section facing away from the grip section; the holding sections are configured with a plurality of holding sections, the shapes and/or the sizes of the holding sections are different, and the main body section is detachably connected with any holding section.

4. A handle data measuring device according to claim 3, wherein one of the body section and the grip section is provided with a connection aperture and the other is provided with a connection portion, the connection portion being in interference fit with the connection aperture; or alternatively, the process may be performed,

one of the main body section and the holding section is provided with a connecting hole, the other one of the main body section and the holding section is provided with a connecting part, the connecting part is inserted into the connecting hole, the handle data measuring device further comprises a limiting part, and the limiting part is connected with the hole wall of the connecting hole and the connecting part.

5. The handle data measurement device of claim 1, further comprising a plurality of analog control keys; the simulation handle is provided with a plurality of adjustment positions which are arranged in an array, and any simulation control key is detachably arranged at any adjustment position.

6. The handle data measuring device of claim 5, wherein the adjustment position includes at least two first adjustment holes, and the analog control key is provided with a first adjustment plug portion corresponding to each of the first adjustment holes.

7. The handle data measuring device according to any one of claims 1 to 6, further comprising a dummy body, wherein two of the dummy handles are provided, and wherein the two dummy handles are respectively connected to opposite sides of the dummy body.

8. The handle data measuring device according to claim 7, wherein the simulation body is provided with a first positioning portion and a first adjusting portion, the simulation handle is provided with a second positioning portion and a second adjusting portion, the first positioning portion is detachably connected with the second positioning portion, and the second adjusting portion is connected with the first adjusting portion along an arrangement direction of the two simulation handles.

9. The handle data measuring device according to claim 8, wherein the first positioning portion includes a positioning hole, the first adjusting portion includes a plurality of second adjusting holes, the plurality of second adjusting holes are arranged in an arc shape with a center of the positioning hole as a center of a circle, the second positioning portion includes a positioning insertion portion, the second adjusting portion includes a second adjusting insertion portion, the positioning insertion portion is inserted into the positioning hole, and the second adjusting insertion portion is inserted into any of the second adjusting holes.

10. The handle data measurement device of claim 9 wherein any adjacent two of the second adjustment apertures are in communication with each other.

11. The handle data measurement device of claim 8 wherein the angle between the two simulated handles is adjusted in the range of 20 ° to 60 °.