CN111779743A

CN111779743A - High-precision electric telescopic device for instrument processing and positioning

Info

Publication number: CN111779743A
Application number: CN202010664392.7A
Authority: CN
Inventors: 不公告发明人
Original assignee: Tian Yingguo
Current assignee: Saikunpeng Information Group Co ltd
Priority date: 2020-07-10
Filing date: 2020-07-10
Publication date: 2020-10-16
Anticipated expiration: 2040-07-10
Also published as: CN111779743B

Abstract

The invention provides a high-precision electric telescopic device for processing and positioning an instrument, wherein when the instrument is processed, a second electric telescopic rod with not too high precision is combined with a telescopic auxiliary structure consisting of a first transverse plate, a first vertical plate and a supporting rod, and the second end of the first transverse plate is inclined downwards, so that the corresponding supporting rod on the first vertical plate is vertically arranged, the minimum telescopic unit length of the second electric telescopic device is reduced, and high-precision telescopic is realized and the price is low; the invention designs the plug pin and the support post on the third telescopic rod so as to ensure that the plug-in unit is positioned under one plug pin every time the second electric telescopic rod extends for a corresponding length, the corresponding support post is abutted with the first transverse plate after the plug-in unit is inserted into the plug pin, so that the first transverse plate is inclined, the corresponding support rod is vertically arranged, and the inclination of the first transverse plate is changed and the vertically arranged support rod is also changed along with the extension of the second electric telescopic rod.

Description

High-precision electric telescopic device for instrument processing and positioning

Technical Field

The invention belongs to the field of instrument processing, and particularly relates to a high-precision electric telescopic device for instrument processing and positioning.

Background

At present, when a precision instrument is machined, the instrument needs to be precisely positioned and machined, so that an electric telescopic rod with very high precision needs to be purchased, but the high-precision electric telescopic rod is expensive. There is a need for an inexpensive and highly precise electric telescopic device.

Disclosure of Invention

The invention provides a high-precision electric telescopic device for processing and positioning an instrument, which aims to solve the problem that the high-precision electric telescopic device for processing and positioning the instrument is expensive at present.

According to a first aspect of the embodiments of the present invention, there is provided a high-precision electric telescopic device for processing and positioning instruments, comprising a first fixing plate, wherein a lower surface of the first fixing plate is fixedly connected to a top end of an outer rod of a first electric telescopic rod capable of extending up and down, a bottom end of an inner rod of the first electric telescopic rod is fixedly connected to an outer rod of a second electric telescopic rod capable of extending left and right, an insert is disposed on an upper side of the inner rod of the second electric telescopic rod, a right end face of the inner rod of the second electric telescopic rod is fixedly connected to a first end of a first transverse plate, a second end of the first transverse plate is fixedly connected to a first end of a first vertical plate, a side of the first vertical plate facing away from the second electric telescopic rod is provided with N support rods, N is an integer greater than 2, and support rods from the second end to the first end of the first vertical plate are respectively a 1 st support rod L to₁～L_NThe included angle between each supporting rod and the first vertical plate is gradually increased, and the included angle is smaller than 90 degrees; the left and right directions are used as an X axis, the positive direction of the X axis is towards the right, the telescopic minimum unit length of the second electric telescopic rod is set as a first length, when the telescopic length of the second electric telescopic rod is unchanged, vertical downward force is applied to the first cross rod 5, the inclination of the first cross rod 5 is gradually increased, each support rod is vertically arranged in sequence, wherein the 1 st support rod L is arranged₁The corresponding X value is X when the device is vertically arranged₁The Nth support rod L_NThe corresponding X value is X when the device is vertically arranged_NFor other support rods L₂～L_N-1X value X corresponding to the vertical arrangement thereof₂～X_N-1At X₁And X_NIs and is connected with X₁The difference values of (A) and (B) are different;

the lower surface of the first fixing plate is further fixed with a vertical plate located on the right side of the second electric telescopic rod, the left side surface of the vertical plate is fixedly connected with an outer rod of a third telescopic rod capable of stretching left and right, N bolts and N pillars located on the right side of the N bolts are arranged on the lower side of an inner rod of the third telescopic rod, and a controller is connected with the first electric telescopic rod and the second electric telescopic rod respectively and used for controlling the first electric telescopic rod and the second electric telescopic rod to stretch so that plug-in units on the second electric telescopic rod can be inserted into the plug-in unitsIn the corresponding bolt, when the plug-in is inserted into the ith bolt from left to right, the ith pillar from right to left is abutted against the first transverse plate, so that the second end of the first transverse plate is inclined downwards, and the included angle between the first transverse plate and the horizontal line is equal to the included angle α between the ith support rod and the first vertical plate_iAt the moment, the ith supporting rod is vertically arranged, and i is an integer which is more than 0 and less than N + 1;

this controller is controlling this first electric telescopic handle and the flexible of second electric telescopic handle, insert this plug-in components in the bolt that corresponds, corresponding pillar and this first diaphragm butt, after making the vertical setting of bracing piece that corresponds, this controller is according to treating flexible length, control this second electric telescopic handle and stretch out and draw back, it is flexible thereupon to drive the third telescopic link simultaneously under the effect of this plug-in components and bolt, in order to keep corresponding the vertical setting of bracing piece, the bracing piece until vertical setting equals this length of treating flexible to the distance between the flexible starting point of this electric telescopic device to the bracing piece of this electric telescopic device, the bracing piece that utilizes this vertical setting carries out high accuracy location to instrument processing, wherein when the flexible starting point of this electric telescopic device is this second electric telescopic handle completely to shrink, the X value that corresponds when this N bracing piece is vertical sets up.

In an optional implementation manner, the corresponding X value X is obtained when the nth supporting plate is vertically arranged_NThe difference value of the X values corresponding to the right end surface of the inner rod of the second electric telescopic rod is equal to the integral multiple of the first length.

In another optional implementation manner, when the telescopic length of the second electric telescopic rod is not changed, the support rods are sequentially vertically arranged, wherein the difference Δ X between the X values respectively corresponding to two adjacent support rods when the two adjacent support rods are vertically arranged is equal to the first length divided by (N-1), and the second electric telescopic rod extends to correspond to the first length of an integral multiple, so that the plug-in unit is located right below the 1 st plug pin from left to right, when the second electric telescopic rod extends for the first length L, the plug-in unit moves right below the next plug pin adjacent to the right, when the plug-in unit inserts the ith plug pin from left to right, the ith support column from right to left abuts against the first transverse plate, at this time, the ith support rod is vertically arranged and the X value corresponding to the ith support rod is abutted against the first transverse plate_i’＝X_N' - (N-i) (L- Δ X) wherein X_N' indicates that when the plug-in is inserted into the Nth bolt from left to right and the Nth support post from right to left abuts against the first transverse plate, the Nth support rod is vertically provided with a corresponding X value.

In another alternative implementation, the minimum unit length that the electric telescopic device can be extended and retracted is Δ X.

In another alternative implementation, each pillar is a straight rod vertically arranged and the length of each pillar gradually increases from left to right.

In another optional implementation, the central vertical shaft of the first electric telescopic rod is taken as the Y axis, the positive direction of the Y axis is downward, and when the ith supporting plate on the first vertical plate is vertically arranged, the Y value corresponding to the free end of the ith supporting plate is greater than the Y value corresponding to the free ends of the second end of the first vertical plate and the rest supporting rods at the moment.

In another optional implementation manner, the extension lines of the support rods all intersect with the same point on the first transverse plate, and for a circle with the same point as a center, the distance from the free end of each support rod to the same point is equal to the radius of the circle.

In another optional implementation manner, the length to be stretched is equal to the distance between the point to be processed on the instrument and the starting point of the electric telescopic device, the instrument is located below the third telescopic device, and the Y value corresponding to the free end of the corresponding support rod is greater than the Y value corresponding to the second electric telescopic rod when the corresponding support rod is vertically arranged.

In another optional implementation manner, the device further comprises a fourth electric telescopic rod, the top end of an outer rod of the fourth electric telescopic rod is fixedly connected with the lower surface of the second fixing plate, the bottom end of an inner rod is fixedly connected with the upper surface of the first fixing plate, and the fourth electric telescopic rod is used for driving the first fixing plate to move up and down so as to move a corresponding vertically-arranged support rod to the instrument and process the to-be-processed point.

The invention has the beneficial effects that:

when the invention is used for processing instruments, the second electric telescopic rod with not too high precision is connected with the first transverse plate and the second transverse plateThe telescopic auxiliary structure composed of a vertical plate and supporting rods is combined, and the second end of the first transverse plate is downwards inclined, so that the corresponding supporting rods on the first vertical plate are vertically arranged, and when the telescopic length of the second electric telescopic rod is unchanged, X corresponding to the 1 st supporting rod and the second N supporting rods are vertically arranged respectively₁And X_NThe difference value is equal to the telescopic minimum length of the second electric telescopic rod, and the X values corresponding to the vertical arrangement of other supporting rods are all positioned at X₁And X_NTherefore, the corresponding support rod is vertically arranged through the telescopic auxiliary structure, the telescopic minimum unit length of the second electric telescopic device can be reduced, high-precision telescopic is realized, and the price is low; the invention acts on the first transverse plate to enable the first transverse plate to incline, so that when the corresponding supporting rod is vertically arranged, an electric telescopic rod is not adopted, but a non-electric third telescopic rod is adopted, the third telescopic rod can be extended and contracted with any length. In addition, the invention designs the plug pin and the support post on the third telescopic rod so as to ensure that the plug-in unit is positioned under one plug pin every time the second electric telescopic rod extends for a corresponding length, after the plug-in unit is inserted into the plug pin, the corresponding support post is abutted against the first transverse plate to enable the first transverse plate to incline, the corresponding support rod is vertically arranged, and the inclination of the first transverse plate is changed and the vertically arranged support rod is also changed along with the extension of the second electric telescopic rod.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of a high-precision electric telescopic device for processing and positioning instruments according to the present invention;

FIG. 2 is a schematic diagram of corresponding X coordinates when the support rods are sequentially and vertically arranged when the telescopic length of the second electric telescopic rod in FIG. 1 is unchanged;

FIG. 3 is a schematic view of the positional relationship between the first transverse plate and each of the posts of FIG. 1 with the inserts inserted sequentially into each of the pins;

FIG. 4 is a schematic diagram of the corresponding X coordinate of the insert of FIG. 1 inserted into the support rods of the pins in a vertical arrangement;

FIG. 5 is a schematic view of the horizontal range of the electric telescopic device of the present invention;

FIG. 6 is a schematic view of the structural relationship between the first cross plate, the first vertical plate and the support rods;

FIG. 7 is a view A-A of FIG. 6;

FIG. 8 is a simulated schematic view of the present invention determining the vertical length of each post on the third telescoping pole;

fig. 9 is an enlarged schematic view of region a in fig. 8.

Detailed Description

In order to make the technical solutions in the embodiments of the present invention better understood and make the above objects, features and advantages of the embodiments of the present invention more comprehensible, the technical solutions in the embodiments of the present invention are described in further detail below with reference to the accompanying drawings.

In the description of the present invention, unless otherwise specified and limited, it is to be noted that the term "connected" is to be interpreted broadly, and may be, for example, a mechanical connection or an electrical connection, or a communication between two elements, or may be a direct connection or an indirect connection through an intermediate medium, and a specific meaning of the term may be understood by those skilled in the art according to specific situations.

Referring to fig. 1, a schematic structural view of an embodiment of the high-precision electric telescopic device for processing and positioning an instrument according to the present invention is shown. This instrument processing is high accuracy electric telescopic device for location can include first fixed plate 1, the lower surface of first fixed plate 1 and the outer pole top fixed connection of the first electric telescopic handle 2 that can stretch out and draw back from top to bottom, the interior pole bottom of this first electric telescopic handle 2 and the flexible second electric telescopic handle about canThe outer pole fixed connection of telescopic link 3, the interior pole upside of this second electric telescopic handle 3 is provided with plug-in components 4 and the interior pole right side end face of this second electric telescopic handle 2 and the first end fixed connection of first diaphragm 5, the second end of this first diaphragm 5 and the first end fixed connection of first riser 6, be provided with a N bracing piece 7 on this first riser 6 one side dorsad this second electric telescopic handle 3, N is for being greater than 2 integer, the bracing piece from its second end to first end on this first riser 6 is 1 st ~ N bracing piece L respectively₁～L_NThe included angle between each supporting rod 7 and the first vertical plate 6 is gradually increased, and the included angle is smaller than 90 degrees; use the left and right direction as the X axle, the X axle positive direction is towards the right, it is first length to establish the minimum unit length of this second electric telescopic handle 3 telescopic, it is unchangeable at this second electric telescopic handle 3's flexible length, and when not with each pillar butt, apply vertical decurrent power to this first horizontal pole 5, make this first horizontal pole 5's gradient crescent, each bracing piece is vertical setting in proper order, combine shown in figure 2 (from the top down is the state when 1 st bracing piece to 5 th bracing piece vertical setting in proper order), wherein 1 st bracing piece L₁X value X corresponding to vertical setting₁And the Nth supporting rod L_NX value X corresponding to vertical setting_NIs equal to the first length for the other support rods L₂～L_N-1X value X corresponding to the vertical arrangement thereof₂～X_N-1At X₁And X_NIs and is connected with X₁The difference of (a) is different from each other.

The lower surface of the first fixing plate 1 is further fixed with a vertical plate 8 located on the right side of the second electric telescopic rod 3, the left side surface of the vertical plate 8 is fixedly connected with an outer rod of a third telescopic rod 9 which can stretch left and right, the lower side of an inner rod of the third electric telescopic rod 9 is provided with N bolts 10 and N pillars 10 located on the right side of the N bolts, a controller is respectively connected with the first electric telescopic rod 2 and the second electric telescopic rod 3 and used for controlling the first electric telescopic rod 2 and the second electric telescopic rod 3 to stretch so as to enable plug-in units 4 on the second electric telescopic rod 3 to be inserted into the corresponding bolts 10, and the combined structure is shown in figure 3 (after the plug-in units 4 are inserted into the first to fifth bolts in sequence from left to right, a first transverse plate is arranged on the secondCorresponding to the position relation diagram of the pillar, correspondingly, the 1 st to 5 th support rods are vertically arranged), when the plug-in unit 4 is inserted into the i-th bolt 10 from left to right, the i-th pillar 11 from right to left is abutted against the first transverse plate 5, so that the second end of the first transverse plate 5 is inclined downwards, and the included angle between the first transverse plate 5 and the horizontal line is equal to the included angle α between the i-th support rod and the first vertical plate 6_iAt this time, the ith supporting rod is vertically arranged, and i is an integer which is greater than 0 and less than N + 1. This controller is controlling this first electric telescopic handle 2 and the flexible of second electric telescopic handle 3, insert this plug-in components 4 in the bolt 10 that corresponds, corresponding pillar 11 and this first diaphragm 5 butt, make the bracing piece 7 vertical setting that corresponds after, this controller is according to treating flexible length, control this second electric telescopic handle 3 and stretch out and draw back, it is flexible along with it to drive third telescopic link 9 under this plug-in components 4 and bolt 10's effect simultaneously, in order to keep corresponding the vertical setting of bracing piece 7, the bracing piece 7 until vertical setting equals this length of treating flexible to the distance between this electric telescopic device's the flexible starting point, the bracing piece that utilizes this vertical setting carries out high accuracy location to instrument processing, wherein when this electric telescopic device's flexible starting point is this second electric telescopic handle completely to shrink, the X value that corresponds when this N number bracing piece 7 is vertical setting.

In this embodiment, in order to facilitate the second electric telescopic rod to accurately adjust the position, the X value X corresponding to the nth support rod 7 when vertically arranged_NThe difference of the X values corresponding to the right end surface of the inner rod of the second electric telescopic rod 3 may be equal to an integral multiple of the first length. Referring to fig. 2, when the telescopic length of the second electric telescopic rod 3 is not changed, the support rods 7 are sequentially vertically arranged, wherein the difference Δ X between the X values respectively corresponding to two adjacent support rods 7 when vertically arranged is equal to the first length divided by (N-1), and the second electric telescopic rod 3 extends by a first length corresponding to an integral multiple, so that after the plug-in unit 4 is located right below the 1 st plug pin 10 from left to right, the plug-in unit 4 moves right below the next plug pin 10 adjacent to right after extending by the first length L. Referring to fig. 2 and 4, when the extension length of the second electric telescopic rod is not changed, the 1 st to the nth support rods are sequentially and vertically arrangedThe X value that corresponds when putting reduces gradually, and the X value that corresponds when the (i + 1) th bracing piece is vertical sets up promptly is less than the X value that corresponds when the vertical setting of the ith bracing piece, and from the top down is with the 1 st to the nth bracing piece vertical setting in proper order in fig. 4, and changes second electric telescopic handle 3 at every turn and will extend L to the right side, and the difference of the X value that corresponds when the vertical setting of the (i + 1) th bracing piece in fig. 4 and the X value that corresponds when the vertical setting of the ith bracing piece is equal to L-DeltaX. That is, as shown in fig. 4, when the plug 4 is inserted into the i-th pin 10 from left to right, the i-th pillar 11 from right to left abuts against the first cross plate 5, and at this time, the i-th support bar 7 is vertically disposed and the corresponding X value X is set to be equal to X_i’＝X_N' - (N-i) (L-DeltaX) wherein X is_N' indicates that when the plug 4 is inserted into the nth pin 10 from left to right and the nth post 11 from right to left abuts against the first horizontal plate 5, the nth support rod 7 is vertically set to a corresponding X value.

When the second electric telescopic rod 3 is extended to the longest, the plug-in 4 is located under the 1 st plug pin 10 from left to right, as shown in fig. 5, the corresponding X value when the 1 st support rod 7 is vertically disposed is the telescopic end point of the electric telescopic device, the difference between the X values of the telescopic start point and the telescopic end point of the electric telescopic device is the horizontal telescopic range of the electric telescopic device, and the minimum telescopic unit length of the electric telescopic device is Δ X. Each strut 11 is a straight rod vertically arranged and has a length gradually increasing from left to right.

According to the embodiment, when the instrument is machined and positioned, the second electric telescopic rod with not too high precision is combined with the telescopic auxiliary structure consisting of the first transverse plate, the first vertical plate and the supporting rods, the second end of the first transverse plate is inclined downwards, so that the corresponding supporting rods on the first vertical plate are vertically arranged, and when the telescopic length of the second electric telescopic rod is not changed, the corresponding X-shaped support rods are vertically arranged, namely the 1 st supporting rod and the N second supporting rods are vertically arranged, so that the X-shaped support rods are vertically arranged₁And X_NThe difference value is equal to the telescopic minimum length of the second electric telescopic rod, and the X values corresponding to the vertical arrangement of other supporting rods are all positioned at X₁And X_NThereby correspondingly supporting the telescopic auxiliary structureThe rod is vertically arranged, so that the telescopic minimum unit length of the second electric telescopic device can be reduced, high-precision telescopic is realized, and the price is low; the invention acts on the first transverse plate to enable the first transverse plate to incline, so that when the corresponding supporting rods are vertically arranged, an electric telescopic rod is not adopted, but a non-electric third telescopic rod is adopted, and the third telescopic rod can be used for stretching in any length. Therefore, the plug-in components are arranged on the second electric telescopic rod, the third telescopic rod is arranged, the plug pins and the support columns are arranged on the third telescopic rod, so that after the plug-in components are inserted into the corresponding plug pins, the corresponding support columns act on the first transverse plate to enable the first transverse plate to incline, and the size of the support columns can be set to any size, so that the first transverse plate can be accurately inclined, the corresponding support rods can be accurately and vertically arranged, and the difference values of the corresponding X values when the adjacent support rods are vertically arranged are equal and can be easily realized. In addition, the invention designs the plug pin and the support post on the third telescopic rod so as to ensure that the plug-in unit is positioned under one plug pin every time the second electric telescopic rod extends for a corresponding length, after the plug-in unit is inserted into the plug pin, the corresponding support post is abutted against the first transverse plate to enable the first transverse plate to incline, the corresponding support rod is vertically arranged, and the inclination of the first transverse plate is changed and the vertically arranged support rod is also changed along with the extension of the second electric telescopic rod.

Referring to fig. 8 and 9, the length and position of the support post 11 on the third telescopic rod 9 are designed according to the following steps:

and S101, setting the horizontal direction of a central shaft of the third telescopic rod as an X axis and the vertical direction as a Y axis, wherein the direction towards the right is the positive direction of the X axis, the direction towards the bottom is the positive direction of the Y axis, and the first transverse plate is set to move forwards for the 1 st time when being abutted with the 1 st support from the right to the left.

Step S102, aiming at the ith support from right to left, wherein i is an integer larger than 1 and smaller than N, straight lines of the first transverse plate when the first transverse plate moves forwards for the (i-1) th time, moves forwards for the (i) th time and moves forwards for the (i + 1) th time respectively and forms corresponding angles with the horizontal line are drawn, and the intersection point of the straight lines drawn correspondingly when the (i-1) th time moves forwards and moves forwards for the (i + 1) th time is taken as a first intersection point (x)_i1，y_i1) And the intersection of the drawn straight lines corresponding to the i-th advance and the i + 1-th advance is taken as a second intersection (x)_i2，y_i2) The coordinates of the free end of the ith strut from right to left are (x)_i0，y_i0) Wherein x is_i0Less than x_i1And is greater than x_i2，y_i0Less than y_i1And is greater than y_i2For example, referring to fig. 3, the left side lines in the drawing indicate lines drawn when the first horizontal plate moves forward 1 to 5 times and the first horizontal plate forms corresponding angles with the horizontal line, and for the right-to-left 4 th pillar, the intersection point of the 3 rd forward movement and the 4 th forward movement of the

lines

③ and ④ is defined as the first intersection point (x)₄₁，y₄₁) The intersection of the

lines

④ and ⑤ drawn corresponding to the 4 th and 5 th advances is taken as the second intersection (x)₄₂，y₄₂) It can be seen that in order to ensure that the 4 th forward movement of the first cross plate only abuts the 4 th post from right to left, the coordinates (x) of the free end of the 4 th post₄₀，y₄₀) In, x₄₀Should be less than x₄₁And is greater than x₄₂，y₄₀Should be less than y₄₁And is greater than y₄₂In addition, as can be seen from fig. 3, when the straight line ④ abuts the 4 th strut from right to left, the X values corresponding to the free ends of the 3 rd and 5 th struts from right to left are both less than X₄₀Therefore, after the first transverse plate moves forward for a corresponding distance, the first transverse plate can only abut against one of the supporting columnsAnd (6) connecting.

Step S103, for the 1 st strut from right to left, determining the coordinate (x) of the free end of the 2 nd strut from right to left₂₀，y₂₀) Coordinate (x) of the corresponding first intersection point₂₁，y₂₁) Determining the coordinates (x) of the free end of the 1 st strut from right to left₁₀，y₁₀) Wherein x is₁₀Greater than x₂₁，y₁₀Greater than y₂₁。

Step S104, aiming at the Nth strut from right to left, determining the coordinate (x) of the free end of the Nth-1 strut from right to left_(N+1)0，y_(N+1)0) Coordinate (x) of the corresponding second intersection point_(N+1)2，y_(N+1)2) Determining the coordinates (x) of the free end of the Nth strut from right to left_N0，y_N0) Wherein x is_N0Less than x_(N+1)2，y_N0Less than y_(N+1)2。

Therefore, the invention designs the vertical length and the arrangement position of each support on the third telescopic rod, and the contact priority sequence between the first transverse plate and each support column in the process that the first transverse plate horizontally moves forwards towards each support column direction is designed (namely, each support column is sequentially contacted with the first transverse plate according to the sequence from right to left), can ensure that only one support post is abutted with the first transverse plate when the first transverse plate moves forwards once in the stepping process, after the first cross plate and the horizontal line are sequentially abutted with each support from right to left, the included angle between the first cross plate and the horizontal line is gradually increased, so that the invention can be seen in that by means of each support on the third telescopic rod, can avoid adopting electronic telescopic link to adjust the contained angle between this first diaphragm and the water flat line at first diaphragm antedisplacement in-process to can guarantee the regulation precision of first diaphragm gradient.

In addition, the controller controls the first electric telescopic rod and the second electric telescopic rod according to the following steps so as to realize high-precision extension and retraction:

step S101, controlling the first electric telescopic rod 2 to extend so as to enable the second electric telescopic rod 3 to be positioned below the third telescopic rod 9;

step S102, judging whether the received length to be stretched is equal to integral multiple of the first length, if so, executing step S103, otherwise, executing step S104;

step S103, controlling the second electric telescopic rod 3 to extend by a corresponding length until the plug-in unit 4 is positioned under the Nth plug pin 10 from left to right, controlling the first electric telescopic rod 2 to contract so as to insert the plug-in unit 4 into the Nth plug pin 10, wherein the Nth pillar 11 from right to left is abutted against the first transverse plate 5, so that the Nth supporting rod 7 is vertically arranged, controlling the second electric telescopic rod 3 to drive the third telescopic rod 9 to stretch, and keeping the Nth supporting rod 7 vertically arranged so as to enable the distance between the X value corresponding to the Nth supporting rod 7 and the stretching starting point of the electric stretching device to be equal to the length to be stretched;

step S104, obtaining a remainder of the length to be stretched and the first length, dividing the remainder by delta X to obtain j, taking the Nth-j plug pins from left to right as plug pins to be inserted, wherein j is an integer greater than 0 and less than N, and executing step S105;

step S105, controlling the second electric telescopic rod 3 to extend by a corresponding length until the plug-in unit 4 is positioned under the Nth-j plug pin 10 from left to right, controlling the first electric telescopic rod 2 to contract so as to insert the plug-in unit 4 into the Nth-j plug pin 10, wherein the Nth-j support post 11 from right to left is abutted against the first transverse plate 5, so that the Nth-j support rod 7 is vertically arranged, controlling the second electric telescopic rod to drive the third telescopic rod 9 to extend and contract, and keeping the Nth-j support rod 7 vertically arranged so that the distance between the X value corresponding to the Nth-j support rod 7 and the extension starting point of the electric extension and contraction device is equal to the length to be extended and contracted.

In this embodiment, since the starting point of the electric telescopic apparatus is the X value corresponding to the nth support rod 7 when the second electric telescopic rod is fully retracted, when the length to be retracted is an integer multiple of the first length, the plug-in unit 4 is inserted into the nth plug pin 10 in step S103, so that the nth support rod 7 is vertically disposed, thereby facilitating the confirmation control of the retracted length of the second electric telescopic rod. Taking N-5 in fig. 4 as an example, since the insert 4 is located right below the 1 st pin 10 from left to right, and the second electric telescopic rod moves to right below the next pin 10 adjacent to the right each time the second electric telescopic rod extends the first length L, the next adjacent support rod is vertically arranged correspondingly, for example, the second electric telescopic rod extends L to the right for the 1 st support rod, and the value of X increases by L, and as shown in fig. 2, the value of X corresponding to the 2 nd support rod when vertically arranged is smaller than the value of X corresponding to the 1 st support rod when vertically arranged by Δ X, and L is greater than Δ X and L is 4- Δ X, so that the value of X corresponding to the 2 nd support rod when vertically arranged is greater than the value of X corresponding to the 1 st support rod when vertically arranged by L- Δ X-4- Δ X-3- Δ X in fig. 4.

For the convenience of corresponding the vertical setting after of bracing piece other bracing pieces can not lead to the fact the influence to the procedure when acting on the instrument to this an electric telescopic handle's the vertical axle in center is the Y axle, and Y axle positive direction is down, and during the vertical setting of the ith bracing piece on this first riser 6, the Y value that its free end corresponds is greater than this moment the Y value that the second of this first riser 6 held and the free end of all the other bracing pieces corresponds. In an example, as shown in fig. 6 and 7, the extension lines of the support rods 7 all intersect with the same point on the first horizontal plate 5, and for a circle with the same point as the center, the distance from the free end of each support rod 7 to the same point is equal to the radius of the circle, and when the first vertical plate 6 is vertically arranged, the support rods 7 are located on the same vertical line. The length of should treating flexible equals the distance between the starting point of treating the processing point and this electric telescopic device on the instrument, and this instrument is located this electric telescopic device's below, and the Y value that its free end corresponds when corresponding the vertical setting of bracing piece is greater than the Y value that this second electric telescopic handle corresponds. In order to process the instrument, the present invention may further include a fourth electric telescopic rod (not shown in the figure), wherein the top end of an outer rod of the fourth electric telescopic rod is fixedly connected to the lower surface of the second fixing plate, the bottom end of an inner rod is fixedly connected to the upper surface of the first fixing plate, and the fourth electric telescopic rod is configured to drive the first fixing plate to move up and down, so as to move the corresponding vertically arranged support rod to the instrument, and process the point to be processed.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It will be understood that the invention is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is to be controlled solely by the appended claims.

Claims

1. The utility model provides an instrument processing location is with high accuracy electric telescopic device, a serial communication port, including first fixed plate, the lower surface of first fixed plate and the outer pole top fixed connection of the first electric telescopic handle that can stretch out and draw back from top to bottom, the interior pole bottom of this first electric telescopic handle and the outer pole fixed connection of the second electric telescopic handle that can control flexible, the interior pole upside of this second electric telescopic handle is provided with plug-in components and this second electric telescopic handle's interior pole right side end face and the first end fixed connection of first diaphragm, the second end of this first diaphragm and the first end fixed connection of first riser, this first riser is provided with a plurality of bracing pieces on the side of this second electric telescopic handle dorsad, N is for being greater than 2 integers, the bracing piece from its second end to first end on this first riser is 1 st ~ N bracing piece L respectively₁～L_NThe included angle between each supporting rod and the first vertical plate is gradually increased, and the included angle is smaller than 90 degrees; the left and right directions are used as an X axis, the positive direction of the X axis is towards the right, the telescopic minimum unit length of the second electric telescopic rod is set as a first length, when the telescopic length of the second electric telescopic rod is unchanged, vertical downward force is applied to the first cross rod 5, the inclination of the first cross rod 5 is gradually increased, each support rod is vertically arranged in sequence, wherein the 1 st support rod L is arranged₁The corresponding X value is X when the device is vertically arranged₁The Nth support rod L_NX value corresponding to vertical settingIs X_NFor other support rods L₂～L_N-1X value X corresponding to the vertical arrangement thereof₂～X_N-1At X₁And X_NIs and is connected with X₁The difference values of (A) and (B) are different;

the lower surface of this first fixed plate still is fixed with the vertical board that is located this second electric telescopic handle's right side, the left surface of vertical board and the outer pole fixed connection of the third telescopic link that can control flexible, the interior pole downside of this third telescopic link is provided with N bolt and is located N pillar on this N bolt right side, this controller is connected with this first electric telescopic handle and second electric telescopic handle respectively, be used for controlling this first electric telescopic handle and second electric telescopic handle are flexible, so that the last plug-in components of this second electric telescopic handle insert in the corresponding bolt, when this plug-in components inserts the ith bolt from left to right, the ith pillar and this first diaphragm butt from right to left, make the second end downward sloping of this first diaphragm, this first diaphragm and horizontal line's contained angle equals the contained angle α of ith bracing piece and this first riser_iAt the moment, the ith supporting rod is vertically arranged, and i is an integer which is more than 0 and less than N + 1;

2. The high-precision electric telescopic device for processing and positioning instruments according to claim 1, wherein the Nth supporting plate is vertically arranged and aligned with the Nth supporting plateCorresponding X value X_NThe difference value of the X values corresponding to the right end surface of the inner rod of the second electric telescopic rod is equal to the integral multiple of the first length.

3. The high-precision electric telescopic device for processing and positioning instruments according to claim 1 or 2, wherein when the telescopic length of the second electric telescopic rod is not changed, the support rods are vertically arranged in sequence, wherein the difference Δ X between the X values respectively corresponding to two adjacent support rods when the two adjacent support rods are vertically arranged is equal to the first length divided by (N-1), and the second electric telescopic rod extends to correspond to the first length of an integral multiple, so that the plug-in unit is located right below the 1 st plug pin from left to right, and when the second electric telescopic rod extends to the first length L, the plug-in unit moves right below the next plug pin adjacent to right, and when the plug-in unit is inserted into the i plug pin from left to right, the i-th support rod from right to left abuts against the first transverse plate, and at this time, the i-th support rod is vertically arranged and the X value corresponding to the i-th support rod is X value_i’＝X_N' - (N-i) (L- Δ X) wherein X_N' indicates that when the plug-in is inserted into the Nth bolt from left to right and the Nth support post from right to left abuts against the first transverse plate, the Nth support rod is vertically provided with a corresponding X value.

4. The high-precision electric telescopic device for machining and positioning instruments according to claim 3, wherein the minimum unit length of the electric telescopic device which can be extended and retracted is Δ X.

5. The high-precision electric telescopic device for processing and positioning instruments according to claim 1, wherein each pillar is a straight rod vertically arranged and gradually increased in length from left to right.

6. The high-precision electric telescopic device for processing and positioning instruments of claim 1, wherein when the central vertical axis of the first electric telescopic rod is taken as the Y axis and the positive direction of the Y axis is downward, and the ith supporting plate on the first vertical plate is vertically arranged, the Y value corresponding to the free end of the ith supporting plate is greater than the Y values corresponding to the second end of the first vertical plate and the free ends of the rest supporting rods.

7. The high-precision electric telescopic device for processing and positioning instruments according to claim 6, wherein the extension lines of the support rods intersect with the same point on the first transverse plate, and for a circle with the same point as the center of the circle, the distance from the free end of each support rod to the same point is equal to the radius of the circle.