CN204819452U - Sieve mechanism that bar storage frame device was used - Google Patents

Abstract

The utility model relates to a sieve mechanism that bar storage frame device was used, including supporting rack, upper and lower parallel arrangement's two sieves and the cylinder of drive sieve, the both ends of above -mentioned sieve are equipped with the end plate, and two above -mentioned end plates are at mutually sidewise grooved long square frame the above -mentioned end plate and the following end plate of the fluting side of end plate are equipped with a plurality of recesses respectively, shang mian the end plate the recess with the recess of following end plate staggers on the horizontal direction, sieve guide rail via the bearing along the supporting rack under the drive of cylinder removes, selects the sample stick from this. Adopt the utility model discloses a bar storage frame device of sieve mechanism can load a large amount of polytype samples stick to select one to supply the next procedure to use respectively, saved the operating space.

Description

A kind of screen plate mechanism of bar storage rack device

Technical field

The utility model relates to metallurgy industry electric furnace thermometric sampling operation auxiliary equipment, relates to a kind of screen plate mechanism of bar storage rack device particularly.

Background technology

In current metallurgy industry, thermometric sampling task is by manually completing, but there is a large amount of risks near electric furnace operation, comprising: the splashing of molten iron, molten steel, drop, and detonation, contact toxic gas, produces and suffocate etc.Use robot to replace manual work, effectively can improve the working environment of operating personnel and reduce labor intensity, improve the economic benefit of enterprise, have very important significance.When robot performs thermometric sampling task, need at a large amount of different types of thermometric sampling rod of the other storage of robot, and need thermometric sampling rod to be delivered to the position that robot is easy to crawl.

In prior art, a kind of bar storage rack can only load a kind of thermometric sampling rod.And in real work, often use polytype thermometric sampling rod, not only need the bar storage rack increasing multiple corresponding form to cause taking space, workspace, also do not have corresponding screen plate mechanism can adapt to the screening of variety classes bar.

Summary of the invention

The purpose of this utility model is to overcome the deficiencies in the prior art, provides a kind of screen plate mechanism being applicable to the thermometric sampling rod storage rack device of Large Copacity multiple types.

The screen plate mechanism of bar storage rack device of the present utility model, described bar storage rack device comprises frame and is fixed on the storage rack in described frame, described screen plate mechanism is arranged on below this storage rack, this screen plate mechanism comprises upper sieve plate, bearing support, lower sieve plate and each sieve plate cylinder of driving, wherein, described bearing support comprises the rectangle framework that two cross sections of splitting are hollow, level is fixed on the two ends of described frame respectively, the outer guide of coupling is installed along its length outside the end face of two bearing supports, the inboard, bottom surface of two bearing supports installs the interior guide rail of coupling along its length, install the bearing coordinated with outer guide bottom described upper sieve plate two ends and can move above described bearing support along described outer guide, install the bearing coordinated with interior guide rail bottom described lower sieve plate two ends and can move below described bearing support along described interior guide rail, described upper sieve plate and described lower sieve plate are " [" shape parts that side is opened wide, be made up of with the cross bar that described end plate is connected at homonymy two pieces of end plates arranged in opposite directions spaced apart, two pieces of described end plates are the rectangle framework of opposite sides opening, multiple groove is offered respectively at the upper surface of the open side of described end plate and lower surface, and the groove of the groove of upper surface and lower surface staggers in the horizontal direction, each cross bar of described upper sieve plate and described lower sieve plate respectively with for driving the cylinder of described upper sieve plate and described lower sieve plate movement to be connected, described cylinder is fixed in described frame.

In the above screen plate mechanism, sampling rod comprises barred body portion and excellent footpath portion; The end plate lower surface of described upper sieve plate equally spaced offers three grooves, and groove width is greater than the barred body portion diameter of described sampling rod and is less than the barred body portion diameter of the described sampling rod of twice; The end plate upper surface of described upper sieve plate equally spaced offers four grooves in axisymmetric mode, wherein, the groove width of two grooves in middle part is wide equal with the lower surface groove of described upper sieve plate, and the groove width of two grooves at both ends is greater than the excellent footpath portion diameter of described sampling rod.

In screen plate mechanism, two end plates of above-mentioned lower sieve plate upper surface reverse symmetry offer four grooves, the upper surface of one of them above-mentioned end plate is greater than the excellent footpath portion diameter of above-mentioned sampling rod near the groove width of two grooves of above-mentioned cross bar side, and the groove width away from two grooves of above-mentioned cross bar side is greater than the barred body portion diameter of above-mentioned sampling rod; Three grooves are offered symmetrically at the lower surface of two end plates of above-mentioned lower sieve plate, groove width in the middle part of the lower surface of one of them above-mentioned end plate is greater than the barred body portion diameter of above-mentioned sampling rod and is less than the barred body portion diameter of the above-mentioned sampling rod of twice, and the groove width near above-mentioned end plate lower surface two ends is greater than excellent footpath portion's diameter of above-mentioned sampling rod and is less than the excellent footpath portion diameter of the above-mentioned sampling rod of twice.

In screen plate mechanism, two end plates of above-mentioned lower sieve plate upper surface reverse symmetry offer four grooves, the upper surface of one of them above-mentioned end plate is greater than the excellent footpath portion diameter of above-mentioned sampling rod near the groove width of two grooves of above-mentioned cross bar side, and the groove width away from two grooves of above-mentioned cross bar side is greater than the barred body portion diameter of above-mentioned sampling rod; Three grooves are offered symmetrically at the lower surface of two end plates of above-mentioned lower sieve plate, groove width in the middle part of the lower surface of one of them above-mentioned end plate is greater than the barred body portion diameter of above-mentioned sampling rod and is less than the barred body portion diameter of the above-mentioned sampling rod of twice, and the groove width near above-mentioned end plate lower surface two ends is greater than excellent footpath portion's diameter of above-mentioned sampling rod and is less than the excellent footpath portion diameter of the above-mentioned sampling rod of twice.

For the bar of concrete structure and size, as barred body, portion is of a size of 46mm, when excellent footpath portion is of a size of 26mm, concrete, and under this screen plate mechanism, the middle groove width of the end plate lower surface of sieve plate is 70mm, and the groove width of the groove of medial launder both sides is 40mm, and separation is 30mm; The end plate upper surface of above-mentioned lower sieve plate is 50mm away from the groove width of two grooves of cross bar side, and separation is 20mm, and the groove width near two grooves of cross bar side is 30mm, and separation is 40mm.To should bar structure and size, the groove width of the lower surface of the end plate of upper sieve plate be 70mm, and separation is 70mm; In the middle of the upper surface of the end plate of above-mentioned upper sieve plate, the groove width of two grooves is 70mm, and the groove width being positioned at two grooves of both sides is 30mm, and separation is 70mm.

In above screen plate mechanism, sieve plate is made up of metal material.

The screen plate mechanism of bar storage rack device of the present utility model, novel structure, design is precisely, storage rack is coordinated to use, first a large amount of bar point kind can be placed on different storing areas, then drive sieve plate motion by cylinder, thus complete the choosing for later process of different bar.Adopt this screen plate mechanism, only need realize choosing of variety classes sampling rod by mobile two pieces of sieve plates.

Accompanying drawing explanation

Fig. 1 is the schematic perspective view of the thermometric sampling rod storage rack device using screen plate mechanism of the present utility model.

Fig. 2 is the right side elevation view of the thermometric sampling rod storage rack device using screen plate mechanism of the present utility model.

Fig. 3 is the left side structure sketch of screen plate mechanism of the present utility model combination storage rack device.

Fig. 4 is the schematic diagram of thermometric sampling rod.

Fig. 5 (a) is the schematic perspective view of lower sieve plate 2 in the utility model, and Fig. 5 (b) is the schematic perspective view of upper sieve plate 1 in the utility model.

Fig. 6 (a) is the lower surface plane of upper sieve plate 1 in the utility model, and Fig. 6 (b) is the top-plan view of upper sieve plate 2 in the utility model.

Fig. 7 (a) is the lower surface plane of lower sieve plate 2 in the utility model, and Fig. 7 (b) is the top-plan view of lower sieve plate 2 in the utility model.

Fig. 8 (a)-8 (e) shows the schematic diagram of the motion state of upper sieve plate 1 and lower sieve plate 2 in the utility model, Fig. 8 (a) represents original state, Fig. 8 (b) represents the motion state I of step one, Fig. 8 (c) represents the motion state II of step 2, Fig. 8 (d) represents that the motion state III, Fig. 8 (e) of step 3 represents the motion state IV of step 4.

Reference numeral:

1 upper sieve plate, 2 times sieve plates, (when watching Fig. 1 with reader, the left-hand side of reader is for left side for 3 left bearing supports, lower same), 4 right bearing supports, 5 frames, 6 cylinders (upper sieve plate 1 is used), 7 cylinders (lower sieve plate 2 is used), 8 storage racks, 80 sampling rods, 81 sampling rods (miner diameter end), 82 sampling rods (bigger diameter end), 301, 401 guide rails (for upper sieve plate 1), 302, 402 guide rails (for lower sieve plate 2), 3001, 4001 linear bearings (for upper sieve plate 1), 3002, 4002 linear bearings (for lower sieve plate 2), 101 end plates (upper sieve plate 1), 102 end plates (upper sieve plate 1), 201 end plates (lower sieve plate 2), 202 end plates (lower sieve plate 2), 103 cross bars (upper sieve plate 1), 203 cross bars (lower sieve plate 2)

Detailed description of the invention

Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail.

Fig. 1 is the schematic perspective view of the thermometric sampling rod storage rack device using screen plate mechanism of the present utility model.Fig. 2 uses the left side elevation view of the thermometric sampling rod storage rack device of screen plate mechanism of the present utility model (with left-hand side when watching Fig. 1 from reader side for left side).Fig. 3 uses the right view of the thermometric sampling rod storage rack device of screen plate mechanism of the present utility model (with right-hand side when watching Fig. 1 from reader side for right side).As shown in FIG. 1 to 3, this thermometric sampling rod storage rack device mainly comprises: frame 5, the storage rack 8 be fixedly installed in frame 5, be fixedly installed on left bearing support 3 above frame 5 left and right sides and right bearing support 4 respectively, be horizontally placed on lower sieve plate 2 between above-mentioned two bearing supports, across bearing support be horizontally placed on upper sieve plate 1 above lower sieve plate 2, for promote upper sieve plate 1 cylinder 6, for promoting the cylinder 7 of lower sieve plate 2.

As shown in Figure 1, frame 5 is for being connected and fixed by the many mutual bolts of aluminium section bar and the cuboid framework formed, and the top of frame 5 is arranged with many crossbeams in parallel, for fixing storage rack 8, cylinder 6, cylinder 7 etc. across the length direction of frame.In the frame 5 upper surface left and right sides, be mounted with left bearing support 3 and right bearing support 4 respectively via bolt.In the utility model, left bearing support 3 and right bearing support 4 are the rectangle framework that cross section is " mouth " font.As shown in Figure 3, upper surface along the left bearing support 3 of " mouth " font is provided with guide rail 301, upper surface inboard along " mouth " font bearing support 3 is provided with guide rail 302, linear bearing 3001,3001 is connected with upper sieve plate 1, and do rectilinear motion along guide rail 301, linear bearing 3002,3002 is connected with lower sieve plate 2, and does rectilinear motion along guide rail 302.Similarly, as shown in Figure 2, at the upper surface of " mouth " font right bearing support 4, guide rail 401 is installed, in the upper surface inboard of " mouth " font right bearing support 4, guide rail 402 is installed, linear bearing 4001,4001 is connected with upper sieve plate 1, and doing rectilinear motion along guide rail 401, linear bearing 4002,4002 is connected with lower sieve plate 2, and does rectilinear motion along guide rail 402.

As shown in FIG. 1 to 3, storage rack 8 is parallel to each other by complex root aluminium section bar and vertically arrangement forms, and often arranging the upper end horizontal positioned aluminium section bar of the aluminium section bar vertically arranged, is connected into an entirety via screw.The lower end often arranging vertical aluminium section bar is all connected and fixed on many crossbeams of frame 5 via bolt.In the utility model embodiment, the aluminium section bar for storage rack 8 is of a size of 20mmx40mmx1200mm, and seven row lined up by this complex root aluminium section bar, often row five, column pitch is corresponding with the diameter of sampling rod, is a bit larger tham the diameter of sampling rod, is advisable can put into sampling rod.The line-spacing of complex root aluminium section bar does not have particular/special requirement, drops be advisable not make sampling rod.As shown in Figure 2, storage rack 8 is divided into six storing areas by above-mentioned seven row aluminium section bars, is respectively A1 storing area, A2 storing area, A3 storing area, A4 storing area, A5 storing area and A6 storing area, can load different types of thermometric sampling rod in different storing areas as required.Thermometric sampling rod respectively transverse horizontal is stacked in each storing area.

Fig. 4 is the schematic diagram of thermometric sampling rod.The size of thermometric sampling rod 80 makes as required, and such as: thermometric sampling rod end (miner diameter end) diameter is 26mm, barred body end (bigger diameter end) diameter is 46mm, and length is 1000mm.A kind of arrangement of thermometric sampling rod is, in A1 ~ A6 storing area, sampling rod is vertically stacked between each row, and another mode is, A1, A2, A3, three kinds of dissimilar tempilsticks are respectively placed in A4 and A5, A6 storing area, in A1 ~ A6 storing area, every district stacks 24 from bottom to top, and six storing areas add up to 144.

Fig. 5 (a) is the schematic perspective view of lower sieve plate 2 in the utility model, and Fig. 5 (b) is the schematic perspective view of upper sieve plate 1 in the utility model.As shown in Fig. 5 (a), lower sieve plate 2 comprises: two pieces separate the end plate 201,202 that certain intervals is arranged in opposite directions and the cross bar 203 be connected and fixed in the same side by above-mentioned two end plates 201,202.End plate 201,202 and cross bar 203 form the " framework of [" shape of a side opening, this lower sieve plate 2 at two ends respectively level embed in " mouth " font opening of left bearing support 3 and right bearing support 4, end plate 201 is fixed on linear bearing 3002,3002 via bolt level connection joint.End plate 202 is fixed on linear bearing 4002,4002 via bolt level connection joint.

As shown in Fig. 5 (b), upper sieve plate 1 comprises: two pieces of cross bars 103 separating end plate 101 that certain intervals arranges in opposite directions, end plate 102 and be connected and fixed in the same side by above-mentioned two end plates 101,102.End plate 101,102 and cross bar 103 formed a side opening " framework of [" shape, end plate 101 is fixed on linear bearing 3001,3001 via bolt level connection joint.End plate 102 is fixed on linear bearing 4001,4001 via bolt level connection joint.

Composition graphs 5 (b), Fig. 6 (a) is the lower surface plane of upper sieve plate 1, and Fig. 6 (b) is the top-plan view of the utility model upper sieve plate 1.As shown in Fig. 6 (a), end plate 101 offers three grooves be spacedly distributed at the position of identical correspondence respectively with the lower surface of end plate 102, and groove width is greater than thermometric sampling rod barred body diameter, is less than the thermometric sampling rod barred body diameter of twice.Such as, composition graphs 4 illustrated dimension, the groove width of end plate 101 and end plate 102 is 70mm, and separation is 70mm, is 65mm near the notch of cross bar 103 side and the spacing of cross bar 103.

Composition graphs 5 (a), as shown in Fig. 6 (b), end plate 101 offers four grooves at the position of identical correspondence respectively with the upper surface of end plate 102, slotting position with the cross central line AA of end plate for axle is arranged axisymmetricly, four away from AA axle is narrow groove, its width of rebate slightly larger than the diameter of thermometric sampling rod 80 end, the size shown in composition graphs 4, such as, the well width of above-mentioned four flutings is 30mm; Near center line AA axle both sides is two sipes, and its width of rebate is less than the barred body diameter of the thermometric sampling rod 80 of twice, the size shown in composition graphs 4, such as, be 70mm, falls two sampling rods be advisable with unlikely from this wide notch.Except four narrow slot pitches away from AA axle are except 35mm from the spacing of end plate two edges, notch spacing is equal, is 70mm.

Composition graphs 5 (a), Fig. 7 (a) is the lower surface plane of lower sieve plate 2, and Fig. 7 (b) is the top-plan view of lower sieve plate 2.As shown in Fig. 7 (a), the lower surface plane of end plate 201 and the lower surface plane of end plate 202 respectively have three grooves, slotting position and groove width left and right symmetrical, fluting in the middle part of end plate 201, end plate 202 is sipes, its width of rebate is greater than the diameter of thermometric sampling barred body 82, being less than the thermometric sampling barred body diameter of twice, to make it possible to fall a sampling rod and unlikelyly to fall two sampling rods and be advisable, such as, is 70mm.The fluting at end plate 201, end plate 202 two ends is narrow groove, and the width of its notch is greater than the diameter of thermometric sampling rod end 81, is less than the diameter of the thermometric sampling rod end 82 of twice, such as, be 40mm.The spacing of groove is 30mm.The distance of the slot pitch end plate two edges at two ends is 65mm.

As shown in Fig. 7 (b), end plate 201 respectively offers four grooves with the upper surface of end plate 202, and the anti-phase correspondence of the slotting position of these four grooves.Two grooves of end plate 201 near cross bar 203 side are narrow groove, and its width of rebate slightly larger than the diameter of thermometric sampling rod end 81, such as, is 30mm.End plate 201 is wider groove away from two grooves of cross bar 203 side, and its width of rebate is slightly larger than the diameter of thermometric sampling barred body 82, and being advisable to make a sampling rod to fall, such as, is 50mm.Anti-phase corresponding with the fluting of end plate 201, two grooves of end plate 202 near cross bar 203 side are wider groove, and its width of rebate is slightly larger than the diameter of thermometric sampling barred body 82, and being advisable to make a sampling rod to fall, such as, is 50mm.End plate 202 is narrow groove away from two grooves of cross bar 203 side, its width of rebate slightly larger than the diameter of thermometric sampling rod end 81, such as, is 30mm, and the spacing of narrow groove is 40mm, the spacing of sipes is 20mm, and the distance at this end plate edge of the slot pitch away from cross bar 203 of end plate 202 is 35mm.

As shown in Figure 1, cylinder 6 moves horizontally for making upper sieve plate 1, it is fastened on air cylinder support 601 via bolt, and air cylinder support 601 is fastened on the cross bar of frame 5 via bolt, and the push rod of cylinder 6 and the cross bar 103 of upper sieve plate 1 are connected and fixed via bolt.The push rod of cylinder 6 promotes upper sieve plate 1 makes it do rectilinear motion via bearing 3001,4001 along guide rail 301,401.

Cylinder 7 moves horizontally for making lower sieve plate 2, and it is connected and fixed on the crossbeam of frame 5 via bolt, and the push rod of cylinder 7 and the cross bar 203 of lower sieve plate 2 are connected and fixed via bolt.The push rod of cylinder 7 promotes lower sieve plate 2 makes it do rectilinear motion via bearing 3002,4002 along guide rail 302,402.

Below, illustrate the utility model screen plate mechanism with reference to Fig. 1 ~ Fig. 3, Fig. 8 (a) ~ Fig. 8 (e) and coordinate the course of work of storage rack in bar is chosen.

As shown in FIG. 1 to 3, storage rack of the present utility model is divided into six storing areas, and wherein the thermometric sampling rod of Class A type is equipped with in A1 storing area and A2 storing area; The thermometric sampling rod of Class B type is equipped with in A3 storing area and A4 storing area; The thermometric sampling rod of Class C type is equipped with in A5 storing area and A6 storing area.

Cylinder 6 and the external PLC of cylinder 7 control, and the push rod of cylinder 6 promotes upper sieve plate 1, makes it do rectilinear motion via linear bearing 3001 and linear bearing 4001 along guide rail 301,401.The push rod of cylinder 7 promotes lower sieve plate 2, makes it do rectilinear motion via linear bearing 3002 and linear bearing 4002 along guide rail 302,402.

Fig. 8 is the schematic diagram of the motion state of the utility model upper sieve plate 1 and lower sieve plate 2, Fig. 8 (a) represents original state, Fig. 8 (b) represents the motion state I of step one, Fig. 8 (c) represents the motion state II of step 2, Fig. 8 (d) represents that the motion state III, Fig. 8 (e) of step 3 represents the motion state IV of step 4.

First, the thermometric sampling rod of Class A type, Class B type, Class C type is placed horizontally at appointed area respectively, the thermometric sampling rod of Class A type is positioned at storing area A1, A2, the thermometric sampling rod of Class B type is positioned at storing area A3, A4, the thermometric sampling rod of Class C type is positioned at storing area A5, A6, each district stacks 24, and wherein, the end (miner diameter end) of tempilstick is positioned at end plate 102,202 side.This original state schematic diagram is as shown in Fig. 8 (a).Now, the three thermometric sampling rods being positioned at bottom in A1, A3, A5 storing area are held unlikely whereabouts by the lower face plate of upper sieve plate 1, and the three thermometric sampling rods being positioned at bottom in A2, A4, A6 storing area are held by the upper surface panel of upper sieve plate 1, unlikely whereabouts.

Step one (state I see shown in Fig. 8 (b)), lower sieve plate 2 keeps original position motionless, upper sieve plate 1 does rectilinear motion along guide rail 301,401 to L direction (left direction of reader) under the driving of cylinder 6, displacement is by external PLC programming Control, in A1, A3, A5 storing area, each one of the thermometric sampling rod of first, second, the third three types is fallen respectively from the notch of upper sieve plate 1 upper surface, wherein, the sampling rod of A1 storing area falls from notch, and continues to fall to extracting position along two walls of A1 storing area; Thermometric sampling rod in A3 storing area falls from the lower surface notch of upper sieve plate 1 because of the movement of upper sieve plate 1, is held afterwards by the lower face plate of lower sieve plate 2.Thermometric sampling rod in A5 storing area falls from the lower surface notch of upper sieve plate 1 because of the movement of upper sieve plate 1, is held afterwards by the upper surface panel of lower sieve plate 2.Meanwhile, the thermometric sampling rod in A2, A4, A6 storing area falls via the upper surface notch of upper sieve plate 1 and is held by the lower face plate of upper sieve plate 1.

Step 2 (state II see shown in Fig. 8 (c)), upper sieve plate 1 keeps the position of above-mentioned steps one motionless, lower sieve plate 2 does rectilinear motion along guide rail 302,402 to L direction (left direction of reader) under the driving of cylinder 7, now, the thermometric sampling rod in A3 storing area falls to extracting position through the lower surface notch of lower sieve plate 2.The thermometric sampling rod of A5 storing area is held by the lower face plate of lower sieve plate 2.

Step 3 (state III see shown in Fig. 8 (d)), upper sieve plate 1 keeps the position of above-mentioned steps one motionless, lower sieve plate 2 does rectilinear motion along guide rail 302,402 to R direction (right direction of reader) under the driving of cylinder 7, get back to initial position, now, the thermometric sampling rod in A5 storing area falls to extracting position through the lower surface notch of lower sieve plate 2.

Realize the object choosing three in six roots of sensation sampling rod thus, complete first pass sampling.

After step 4 (state IV see shown in Fig. 8 (e)), reverse drive upper sieve plate 1, it is made to move back to initial position to the right, now, in A2, A4, A6 storing area, fall each one of the thermometric sampling rod of first, second, the third three types respectively from the lower surface notch of upper sieve plate 1, wherein, the sampling rod of A2 storing area falls to extracting position from notch; Thermometric sampling rod in A4 storing area falls from the lower surface notch of upper sieve plate 1 because of the movement of upper sieve plate 1, is held afterwards by the lower face plate of lower sieve plate 2.Thermometric sampling rod in A6 storing area falls from the lower surface notch of upper sieve plate 1 because of the movement of upper sieve plate 1, is held afterwards by the upper surface panel of lower sieve plate 2.Meanwhile, the thermometric sampling rod in A1, A3, A5 storing area falls via the upper surface notch of upper sieve plate 1 and is held by the lower face plate of upper sieve plate 1.

Afterwards, repeat above-mentioned steps two ~ step 3, what realize six roots of sensation sampling rod thus chooses work.

Upper sieve plate 1 or lower sieve plate 2 often do and once move horizontally, and have a thermometric sampling rod to fall, for next procedure from upper sieve plate 1 or lower sieve plate 2.

Screen plate mechanism of the present utility model coordinates storage rack work, novel structure, and design precisely, achieves the accurate selection to sampling bar.

Claims (10)

1. a screen plate mechanism for bar storage rack device, described bar storage rack device comprises frame and is fixed on the storage rack in described frame, and described screen plate mechanism is arranged on below this storage rack, it is characterized in that,

Comprise: upper sieve plate, bearing support, lower sieve plate and drive each sieve plate cylinder, wherein,

Described bearing support comprises the rectangle framework that two cross sections of splitting are hollow, level is fixed on the two ends of described frame respectively, install the outer guide of coupling outside the end face of two bearing supports along its length, the inboard, bottom surface of two bearing supports installs the interior guide rail of coupling along its length;

Install the bearing coordinated with outer guide bottom described upper sieve plate two ends and can move above described bearing support along described outer guide,

Install the bearing coordinated with interior guide rail bottom described lower sieve plate two ends and can move below described bearing support along described interior guide rail,

Described upper sieve plate and described lower sieve plate are " [" shape parts that side is opened wide, be made up of with the cross bar that described end plate is connected at homonymy two pieces of end plates arranged in opposite directions spaced apart, two pieces of described end plates are the rectangle framework of opposite sides opening, multiple groove is offered respectively at the upper surface of the open side of described end plate and lower surface, and the groove of the groove of upper surface and lower surface staggers in the horizontal direction

Each cross bar of described upper sieve plate and described lower sieve plate respectively with for driving the cylinder of described upper sieve plate and described lower sieve plate movement to be connected, described cylinder is fixed in described frame.

2. the screen plate mechanism of bar storage rack device as claimed in claim 1, is characterized in that: described bar is thermometric sampling sampling rod, comprises barred body portion and excellent footpath portion,

The end plate lower surface of described upper sieve plate equally spaced offers three grooves, and groove width is greater than the barred body portion diameter of described sampling rod and is less than the barred body portion diameter of the described sampling rod of twice;

The end plate upper surface of described upper sieve plate equally spaced offers four grooves in axisymmetric mode, wherein, the groove width of two grooves in middle part is wide equal with the lower surface groove of described upper sieve plate, and the groove width of two grooves at both ends is greater than the excellent footpath portion diameter of described sampling rod.

3. the screen plate mechanism of bar storage rack device as claimed in claim 1, is characterized in that: described bar is thermometric sampling sampling rod, comprises barred body portion and excellent footpath portion,

Two end plates of described lower sieve plate upper surface reverse symmetry offer four grooves, the upper surface of end plate described in one of them is greater than the excellent footpath portion diameter of described sampling rod near the groove width of two grooves of described cross bar side, and the groove width away from two grooves of described cross bar side is greater than the barred body portion diameter of described sampling rod;

Three grooves are offered symmetrically at the lower surface of two end plates of described lower sieve plate, groove width in the middle part of the lower surface of end plate described in one of them is greater than the barred body portion diameter of described sampling rod and is less than the barred body portion diameter of the described sampling rod of twice, and the groove width near described end plate lower surface two ends is greater than excellent footpath portion's diameter of described sampling rod and is less than the excellent footpath portion diameter of the described sampling rod of twice.

4. the screen plate mechanism of bar storage rack device as claimed in claim 2, is characterized in that:

Two end plates of described lower sieve plate upper surface reverse symmetry offer four grooves, the upper surface of end plate described in one of them is greater than the excellent footpath portion diameter of described sampling rod near the groove width of two grooves of described cross bar side, and the groove width away from two grooves of described cross bar side is greater than the barred body portion diameter of described sampling rod;

Three grooves are offered symmetrically at the lower surface of two end plates of described lower sieve plate, groove width in the middle part of the lower surface of end plate described in one of them is greater than the barred body portion diameter of described sampling rod and is less than the barred body portion diameter of the described sampling rod of twice, and the groove width near described end plate lower surface two ends is greater than excellent footpath portion's diameter of described sampling rod and is less than the excellent footpath portion diameter of the described sampling rod of twice.

5. the screen plate mechanism of bar storage rack device as claimed in claim 3, is characterized in that:

Described barred body portion is of a size of 46mm, and described excellent footpath portion is of a size of 26mm, and the middle groove width of the end plate lower surface of described lower sieve plate is 70mm, and the groove width of the groove of medial launder both sides is 40mm, and separation is 30mm; The end plate upper surface of described lower sieve plate is 50mm away from the groove width of two grooves of cross bar side, and separation is 20mm, and the groove width near two grooves of cross bar side is 30mm, and separation is 40mm.

6. the screen plate mechanism of bar storage rack device as claimed in claim 4, is characterized in that:

Described barred body portion is of a size of 46mm, and described excellent footpath portion is of a size of 26mm, is 70mm in the middle groove width of the end plate lower surface of described lower sieve plate, and the groove width of the groove of medial launder both sides is 40mm, and separation is 30mm; The end plate upper surface of described lower sieve plate is 50mm away from the groove width of two grooves of cross bar side, and separation is 20mm, and the groove width near two grooves of cross bar side is 30mm, and separation is 40mm.

7. the screen plate mechanism of bar storage rack device as claimed in claim 2, is characterized in that:

Described barred body portion is of a size of 46mm, and described excellent footpath portion is of a size of 26mm, is 70mm in the groove width of the lower surface of the end plate of described upper sieve plate, and separation is 70mm; In the middle of the upper surface of the end plate of described upper sieve plate, the groove width of two grooves is 70mm, and the groove width being positioned at two grooves of both sides is 30mm, and separation is 70mm.

8. the screen plate mechanism of bar storage rack device as claimed in claim 5, is characterized in that:

Described barred body portion is of a size of 46mm, and described excellent footpath portion is of a size of 26mm, is 70mm in the groove width of the lower surface of the end plate of described upper sieve plate, and separation is 70mm; In the middle of the upper surface of the end plate of described upper sieve plate, the groove width of two grooves is 70mm, and the groove width being positioned at two grooves of both sides is 30mm, and separation is 70mm.

9. the screen plate mechanism of bar storage rack device as claimed in claim 6, is characterized in that:

Described barred body portion is of a size of 46mm, and described excellent footpath portion is of a size of 26mm, is 70mm in the groove width of the lower surface of the end plate of described upper sieve plate, and separation is 70mm; In the middle of the upper surface of the end plate of described upper sieve plate, the groove width of two grooves is 70mm, and the groove width being positioned at two grooves of both sides is 30mm, and separation is 70mm.

10. the screen plate mechanism of the bar storage rack device as described in as arbitrary in claim 1 to 9, is characterized in that: described sieve plate is made up of metal material.