CN110595981A - Concrete impermeability instrument - Google Patents
Concrete impermeability instrument Download PDFInfo
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- CN110595981A CN110595981A CN201910944760.0A CN201910944760A CN110595981A CN 110595981 A CN110595981 A CN 110595981A CN 201910944760 A CN201910944760 A CN 201910944760A CN 110595981 A CN110595981 A CN 110595981A
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- 238000012360 testing method Methods 0.000 claims abstract description 158
- 230000003287 optical effect Effects 0.000 claims description 10
- 230000003487 anti-permeability effect Effects 0.000 claims description 2
- 230000009471 action Effects 0.000 abstract description 3
- 238000000034 method Methods 0.000 abstract description 3
- 230000008569 process Effects 0.000 abstract description 2
- 238000007789 sealing Methods 0.000 description 30
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 18
- 238000001514 detection method Methods 0.000 description 4
- 230000007246 mechanism Effects 0.000 description 4
- 238000006073 displacement reaction Methods 0.000 description 3
- 238000007689 inspection Methods 0.000 description 3
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000035515 penetration Effects 0.000 description 2
- 239000000243 solution Substances 0.000 description 2
- 230000005856 abnormality Effects 0.000 description 1
- 239000002969 artificial stone Substances 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 210000002421 cell wall Anatomy 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 239000000295 fuel oil Substances 0.000 description 1
- 238000002347 injection Methods 0.000 description 1
- 239000007924 injection Substances 0.000 description 1
- 239000007788 liquid Substances 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 239000003921 oil Substances 0.000 description 1
- 230000000149 penetrating effect Effects 0.000 description 1
- 238000003908 quality control method Methods 0.000 description 1
- 210000003813 thumb Anatomy 0.000 description 1
Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N15/00—Investigating characteristics of particles; Investigating permeability, pore-volume or surface-area of porous materials
- G01N15/08—Investigating permeability, pore-volume, or surface area of porous materials
- G01N15/082—Investigating permeability by forcing a fluid through a sample
- G01N15/0826—Investigating permeability by forcing a fluid through a sample and measuring fluid flow rate, i.e. permeation rate or pressure change
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- Chemical & Material Sciences (AREA)
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- Analytical Chemistry (AREA)
- Dispersion Chemistry (AREA)
- Health & Medical Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Fluid Mechanics (AREA)
- Biochemistry (AREA)
- General Health & Medical Sciences (AREA)
- General Physics & Mathematics (AREA)
- Immunology (AREA)
- Pathology (AREA)
- Investigating Strength Of Materials By Application Of Mechanical Stress (AREA)
- Sampling And Sample Adjustment (AREA)
Abstract
The invention discloses a concrete impermeability instrument, which comprises a lifting column and at least two sets of test mold mounting plates, wherein the lifting column is a spline shaft, when a spline sleeve is positioned on a smooth shaft section on the spline shaft, a device which drives the spline sleeve to rotate in a test mold mounting plate locking device enables the spline sleeve to rotate by a half spline tooth angle, an external spline on the spline shaft is opposite to an internal spline tooth on the spline sleeve, so that the spline shaft cannot slide in the spline sleeve, and the lifting column can drive the mounting plates on the test molds to lift and lower to open or close the test molds. And in the process of driving the spline sleeve to rotate, the driving plate connected to the lower end of the spline sleeve rotates simultaneously, the driving pin shaft slides along the pin shaft supporting seat, and the other end of the pin shaft is inserted into the pin hole of the locking seat to lock the test mold between the upper mounting plate and the lower mounting plate of the test mold. The test mold mounting plate locking device and the test mold locking device share one air cylinder, the structure is simple, the cost is low, the two sets of locking devices act simultaneously, the operation steps are few, the sequential action sequence is avoided, and misoperation cannot occur.
Description
Technical Field
The invention relates to the technical field of concrete quality detection, in particular to a detection device for a concrete impermeability test.
Background
The concrete is an artificial stone widely used in buildings, and the impermeability of the concrete is an important index for evaluating the quality and durability of the concrete and is also a necessary inspection index for strict quality control of the concrete in each engineering quality supervision station. Engineering that concrete has impermeability requirement: such as hydraulic engineering, port engineering, road and bridge engineering, underground structural engineering, etc. The impermeability refers to the resistance of the materials used in the construction to the penetration of water and/or other liquid (light oil, heavy oil) media under pressure.
The concrete impermeability instrument is used for detecting the waterproof performance of hardened concrete and determining impermeability grade, and is a necessary measuring instrument for concrete premixing enterprises and building engineering quality detection laboratories. The concrete impermeability instrument utilizes the principle that the pressure in a sealed container is equal everywhere, the pressure of the whole system is transmitted by a water pump and is connected with the pressure container, a control valve, a test die holder and the like through pipelines, the pressure is output by the water pump to enter the pressure container and then is transmitted to each test piece system to carry out loading test, the pressure instrument and a controller are used for controlling the magnitude of the pressurizing pressure, the water pressure is permeated into a test piece which is arranged in the test die from bottom to top, and therefore the impermeability of the test piece is measured and the impermeability grade of the test piece is calculated.
The period of the concrete impermeability test is long, the past concrete impermeability test can only be performed by one group of test tests, a plurality of test instruments are needed, the test efficiency is low, and the occupied space is large, so a corresponding solution is provided in the prior art, for example, the applicant obtains patent No. 201730163179.7 and an appearance design patent named as a stacked concrete impermeability test, and the patentee obtains patent No. 201510332464.7 and a locking device and an invention patent of a full-automatic concrete impermeability test adopting the locking device at dawn. The technical scheme of patent No. 201510332464.7 has high automation degree, each device is provided with 24 sets of dies (called as sealing penetrating devices in the patent document) which can simultaneously perform impermeability tests on 24 samples (see the attached drawings 1 to 4), the 24 sets of dies are respectively arranged on 4 layers, each layer of 6 sets of dies are arranged between an upper fixing seat 213 and a lower fixing seat 213, each die comprises a sealing base 41 and a sealing sleeve matched with the shape of a concrete test block, the sealing base 41 is fixed on the upper surface of the fixing seat 213 on the layer, the sealing sleeve is fixed on the lower surface of the fixing seat 213 on the upper layer, the test block is arranged in the sealing sleeve, the fixing seats 213 are provided with through holes 2130, the lifting columns 212 penetrate through the through holes 2130 of the fixing seats 213, the fixing seats 213 on the upper layer are locked on the lifting columns 212 by locking pieces 214, the up-down displacement driving device 211 drives the lifting columns 212 to lift and further drive the, so that the seal sleeve is separated from the seal base 41 (loading and unloading the test piece) or the seal sleeve is buckled on the seal base 41 (performing a water seepage test on the test piece), and when the water seepage test is performed on the test piece, the locking is released; therefore, when the test abnormality (such as the leakage of the sealing element) occurs in the sealing sleeve on the layer, the upper layer fixing seat 213 on the layer is locked on the lifting column 212 by the locking piece 214, the lifting column 212 is driven to ascend by the up-and-down displacement driving device 211, the upper layer fixing seat 213 is driven to ascend, the sealing sleeve is separated from the sealing base 41, and the test of test molds on other layers is not influenced; the locking member 214 includes a cylinder 2140 and a clamping plate 2141, the cylinder 2140 is fixed to the lower surface of the upper fixing seat 213, the rod end of the cylinder 2140 is connected to the clamping plate 2141 having an arc-shaped notch 2142 at the end, the lifting column 212 is provided with a number of ring-shaped slots 2120 corresponding to the number of the fixing seats 213, and the clamping plate 2141 is driven by the cylinder 2140 to be clamped into the slots 2120. The pressure providing mechanism 30 injects water with a predetermined pressure through the water injection through hole 4110 on the sealing base 41 to perform impermeability test on the concrete test block in the sealing and permeating device 40, and in order to maintain the test pressure, the sealing sleeve and the sealing base 41 need to be locked together; the locking device comprises a first locking structure 23, a second locking structure 24 and a locking state control device (see fig. 5 to 9 thereof), wherein the first locking structure 23 is arranged on a disc 230 which can rotate around a positioning column 412 at the lower part of the sealing base 41, and is characterized in that a convex locking sheet 235 is arranged on the outer circumference of the disc 230, a toggle groove 236 is arranged on the lower surface, and the opening of the toggle groove 236 extends to the edge of the lower surface of the disc 230; the second locking structure 24 is arranged at the lower end of the lower pressing ring 423 of the sealing sleeve, and is particularly characterized in that a locking sheet inlet 243 is arranged on a second annular platform 242 at the lower end of an annular side wall 241 of the lower pressing ring 423; the locking state control device 22 comprises an air cylinder 220 and a locking pulling plate disc 221, the locking pulling plate disc 221 is sleeved on the lifting column 212 through a through hole 2210 and can rotate around the lifting column 212, a pulling plate 2211 is arranged on the edge of the locking pulling plate disc 221, and the pulling plate 2211 is inserted into a pulling groove 236 of the disc 230 of the corresponding first locking structure 23; the air cylinder 220 is fixed on the fixing seat 213 of the layer, the rod end of the air cylinder 220 is hinged to the locking pulling plate disc 221, the piston rod of the air cylinder 220 stretches and retracts to pull the locking pulling plate disc 221 to rotate by taking the lifting column 212 as a shaft, and then the pulling piece 2211 of the locking pulling plate disc 221 is used for driving the disc 230 to rotate relative to the lower pressing ring 423 of the sealing sleeve; the test piece is placed on the sealing base 41, the up-and-down displacement driving device 211 drives the lifting column 212 to descend at first, and then drives the upper fixing seat 213 to descend, so that the sealing sleeve is buckled on the sealing base 41, the locking sheet 235 of the first locking structure 23 arranged on the disc 230 enters from the locking sheet inlet 243 of the second locking structure 24, then the locking state control device 22 drives the disc 230 and the sealing sleeve to rotate relatively, the locking sheet 235 of the disc 230 is clamped between the first annular platform 241 and the second annular platform 242 of the second locking structure 24, and the sealing sleeve and the sealing base 41 are locked up and down.
The above analysis shows that the technical scheme needs two sets of cylinders for locking, the cylinder 2140 is used for locking the fixing seat 213, and the cylinder 220 is used for locking the sealing sleeve and the sealing base 41, and has the disadvantages of complicated structure, multiple operation steps and the like due to the sequential action sequence.
Disclosure of Invention
The invention aims to provide a concrete impermeability instrument with simple structure, convenient operation and low cost aiming at the defects in the prior art.
In order to achieve the purpose, the invention adopts the following technical scheme:
the utility model provides a concrete anti-permeability apparatus, includes lift post, lift drive arrangement, at least two sets of examination mould mounting panels, examination mould mounting panel locking device and examination mould locking device, characterized by: the lifting column is a spline shaft, a spline housing is arranged on the spline shaft, and an external spline on the spline shaft is meshed with an internal spline on the spline housing, so that the spline shaft can slide in the spline housing; the mould mounting panel locking device that tries mould includes quantity and the corresponding spline housing of group's number of trying the mould mounting panel, set up in the epaxial smooth shaft section of integral key, drive spline housing pivoted device, the spline housing rotates to be connected on trying the mould mounting panel, when the spline housing is located the epaxial smooth shaft section of integral key, drive spline housing pivoted device makes the spline housing rotate the angle of half spline tooth, the epaxial external splines of integral key is relative with the internal spline tooth on the spline housing, make the integral key shaft can not slide in the spline housing.
Through adopting above-mentioned technical scheme, lift drive arrangement can drive the lift post and go up and down, drives the examination mould mounting panel and goes up and down, opens or is closed with the examination mould, conveniently carries out the loading and unloading of test piece, sealing device's inspection etc..
Among the impervious appearance of foretell concrete, the examination mould mounting panel include examination mould upper mounting panel and examination mould lower mounting panel, drive spline housing pivoted device include the bearing frame, dial ring and cylinder, examination mould upper mounting panel and examination mould lower mounting panel all are equipped with central through-hole, the lower extreme of bearing frame links to each other with examination mould upper mounting panel, the upper end of bearing frame links to each other with the examination mould lower mounting panel on upper strata, the lateral wall of spline housing rotates through first bearing and connects in the bearing frame, the hole of spline housing can rotate around the epaxial optical axis of spline, dial the ring and connect in the upper end of spline housing, be equipped with the lug of evagination on the outer circumference of dial ring, the cylinder is installed on the examination mould lower mounting panel on upper strata, the rod end of cylinder is articulated with the lug on the dial ring, the flexible pulling dial ring rotation of the piston rod of cylinder.
By adopting the technical scheme, the spline housing is driven by the air cylinder in rotation, the air cylinder can be controlled by the control system in operation, the automation degree is high, and the control is simple and convenient.
In the concrete impermeability instrument, the test mold locking device comprises,
each group of locking seats comprises an upper locking seat fixed on the lower surface of the upper mounting plate of the test mold and a lower locking seat fixed on the upper surface of the lower mounting plate of the test mold, the upper end of the lower locking seat is provided with a pin hole A, the upper locking seat is in an inverted U shape, the upper end of the lower locking seat can be inserted between two side walls of the U shape, and the two side walls of the U shape are provided with pin holes B corresponding to the pin holes A;
the drive plate is connected with the lower end of the spline housing, at least two arc-shaped grooves are arranged on the drive plate,
the upper end of the pin roll supporting seat is connected with the lower surface of the upper mounting plate of the test mould, the lower end of the pin roll supporting seat is provided with a shaft sleeve,
the pin shaft is matched with the shaft sleeve and can slide in the shaft sleeve, one end of the pin shaft is connected with a second bearing which can horizontally rotate, the other end of the pin shaft can be inserted into the pin hole A and the pin hole B, and the second bearing can roll along the groove wall of the arc-shaped groove on the drive plate.
By adopting the technical scheme, when a piston rod of the air cylinder extends out to push the shifting ring to rotate, the spline housing is driven to rotate by an angle of half spline teeth, an external spline on the spline shaft is opposite to internal spline teeth on the spline housing, the pin shaft is not inserted into the pin hole A and the pin hole B of the locking seat, the lifting driving device drives the lifting column to lift, the mounting plate on the test mold is driven to lift, the test mold is opened or closed, and then the loading and unloading of a test piece, the inspection of the sealing device and the like can be carried out;
after the test piece is installed and the sealing device is checked, the lifting driving device drives the lifting column to descend to drive the mounting plate on the test mold to descend, and the mold is closed; then the control device starts the air cylinder to work, a piston rod of the air cylinder retracts to pull the shifting ring to rotate, the spline housing is driven to rotate by an angle of a half spline tooth, when the external spline tooth on the spline shaft is opposite to the internal spline groove on the spline housing, the lifting driving device can drive the lifting column to lift and pass through the spline housing, and the operation of dies on other trial die mounting plates is not influenced; the piston rod of cylinder retracts and pulls the thumb ring to rotate, drives the spline housing pivoted in-process, connects in the driver plate of spline housing lower extreme and rotates simultaneously, and the second bearing of the arc wall drive pin axle one end on the driver plate rolls along the cell wall of arc wall and drives the round pin axle and slide along the axle sleeve on the round pin axle supporting seat, and the other end of round pin axle inserts gradually in pinhole A, the pinhole B of locking seat, will try the mould locking on trying the mould between mounting panel and the mounting panel under trying the mould.
In the concrete impermeability instrument, a support sleeve is arranged between the upper test mould mounting plate and the lower test mould mounting plate on the upper layer;
by adopting the technical scheme, the upper mounting plate of the test mould and the lower mounting plate of the upper test mould can form a whole, and the rigidity is good.
Furthermore, the upper locking seat is provided with a rotation stopping screw, the pin shaft is correspondingly provided with a guide groove, and the rotation stopping screw extends into the guide groove and can slide in the guide groove.
By adopting the technical scheme, the second bearing can always keep a horizontal rotating posture in the arc-shaped groove, can roll along the groove wall smoothly, and is not blocked.
The invention has the beneficial effects that:
1. the test mold mounting plate locking device and the test mold locking device share one air cylinder, so that the structure is simple and the cost is low;
2. the air cylinder drives the test mold mounting plate locking device and the test mold locking device to act simultaneously, so that the operation steps are few, the action sequence is not successive, and misoperation cannot be caused.
Drawings
Fig. 1 is a perspective view of the present invention.
Fig. 2 is a schematic front view of the present invention.
Fig. 3 is a schematic cross-sectional view of the present invention.
Fig. 4 is a schematic sectional view a-a in fig. 2.
Fig. 5 is a schematic sectional view B-B in fig. 2.
Fig. 6 is a schematic sectional view of C-C in fig. 4.
Fig. 7 is a schematic view showing the opened state of the mold on a certain layer of the test mold mounting plate according to the present invention.
Fig. 8 is a schematic view of a test mold mounting plate locking device and a test mold locking device in the invention.
Fig. 9 is a schematic view (from bottom to top) of the trial mold locking apparatus of the present invention.
In the figure: the device comprises a threading pipe 1, a test die upper mounting plate 2, a lower locking seat 3, a pin hole A3-1, a shifting ring 4, a lug 4-1, a hinge shaft 5, an upper nut 6, a first key 7, a lifting column 8, a smooth shaft section 8-1, a spline sleeve 9, a bearing seat 10, a guide shaft 11, an upper locking seat 12, a pin hole B12-1, a guide groove 13, a rotation stop screw 14, a pin shaft 15, a pin shaft support 16, a shaft sleeve 17, a second bearing 18, a shifting plate 19, an arc groove 19-1, a first bearing 20, a gasket 21, a set screw 22, a guide sleeve 23, a cylinder 24, a lifting cylinder 25, a lower nut 26, a test die lower mounting plate 27, a top plate 28 times, a top plate 29, a support sleeve 30, a test die 31, an upper workbench 32, a lower workbench 33, an upright post 34 and a second key 35.
Detailed Description
In order to clearly illustrate the technical features of the present solution, the present invention is further illustrated by the following non-limiting examples in combination with the accompanying drawings.
Referring to fig. 1 to 7, a concrete impermeability tester comprises an upper workbench 32, a lower workbench 33, a top plate 29, a lifting column 8, a lifting driving device, 4 groups of test mold mounting plates, a test mold mounting plate locking device and a test mold locking device, wherein the upper workbench 32 and the lower workbench 33 are rectangular and are connected through 4 corner columns 34, the lifting driving device is a lifting cylinder 25 fixed on the lower workbench 33, 6 sets of test molds are arranged on each group of test mold mounting plates, and the 6 sets of test molds are positioned on a first circumference and are uniformly distributed; the upper workbench 32 is connected with the top plate 29 through the guide shaft 11, the upper end of the guide shaft 11 is fixed on the top plate 29, the lower end of the guide shaft 11 is fixed on the upper workbench 32, the test mold mounting plate is provided with the guide sleeve 23, the guide sleeve 23 can slide along the guide shaft 11, so that the test mold mounting plate can slide along the guide posts, the guide posts are positioned on the second circumference and are uniformly distributed, and the diameter of the second circumference is larger than that of the first circumference; the second circumference is also provided with a threading pipe 1 which is arranged at intervals with the guide post and is uniformly distributed for a control line, a cable, a detection line, an air pipe and a water pipe to pass through.
Referring to fig. 2 to 8, each set of test mold mounting plates includes a test mold upper mounting plate 2 and a test mold lower mounting plate 27, and the test mold upper mounting plate 2 and the test mold lower mounting plate 27 are both provided with a central through hole; the lifting column 8 is a spline shaft, a spline housing 9 is arranged on the spline shaft, and an external spline on the spline shaft is meshed with an internal spline on the spline housing 9, so that the spline shaft can slide in the spline housing 9; the mold testing mounting plate locking device comprises 4 sets of mold testing mounting plate locking devices corresponding to the number of sets of the mold testing mounting plates, each set of mold testing mounting plate locking device comprises a spline housing 9, a smooth shaft section 8-1 arranged on the spline shaft and a device for driving the spline housing 9 to rotate, each set of mold testing mounting plate locking device comprises a bearing seat 10, a shifting ring 4 and an air cylinder 24, the bearing seats 10 penetrate through central through holes of an upper mold testing mounting plate 2 and a lower mold testing mounting plate 27 from top to bottom, the lower ends of the bearing seats are connected to the upper mold testing mounting plate 2, the upper ends of the upper mold testing mounting plate 27 are connected to the lower mold testing mounting plate 27 on the upper layer, the upper ends and the lower ends of the bearing seats 10 are respectively provided with a first bearing 20, the outer side wall of the spline housing 9 is rotatably connected to the bearing seats 10 through the first bearings 20, an inner hole of the spline housing 9 can rotate around the optical axis on the spline shaft, the upper portion of the spline housing 9 is provided with an external, in order to prevent the shifting ring 4 and the spline housing 9 from rotating relatively, the shifting ring 4 is connected with the spline housing 9 through a first key 7, a convex lug 4-1 is arranged on the outer circumference of the shifting ring 4, a hinge shaft 5 is arranged on the lug 4-1, an air cylinder 24 is arranged on an upper test mold lower mounting plate 27, the rod end of the air cylinder 24 is hinged with the hinge shaft 5 on the lug 4-1 of the shifting ring 4, and a piston rod of the air cylinder 24 stretches and retracts to pull the shifting ring 4 to rotate so as to drive the spline housing 9 to rotate.
The spline shaft penetrates through the spline housing 9 on each set of test die mounting plates, the lower end of the spline shaft is connected with the rod end of the lifting air cylinder 25, 4 sections of optical shaft sections 8-1 are arranged on the spline shaft at intervals, each section of optical shaft section 8-1 corresponds to the closed state of one layer of test die, the length of the optical shaft section 8-1 is slightly larger than that of the spline housing 9, when the spline housing 9 is located on the optical shaft section 8-1 on the spline shaft, the spline housing 9 is rotated by a device for driving the spline housing 9 to rotate by an angle of half spline teeth, and the external splines on the spline shaft are opposite to the internal spline teeth on the spline housing 9, so that the spline shaft cannot slide in the spline.
Referring to fig. 5 to 9, the test mold locking device is also provided with 4 sets, each set comprises 6 sets of locking seats, 1 drive plate 19, 6 pin roll supporting seats 16 and 6 pin rolls 15, each set of locking seat is positioned between two sets of test molds adjacent to each other, each set of locking seat comprises an upper locking seat 12 fixed on the lower surface of the upper test mold mounting plate 2 and a lower locking seat 3 fixed on the upper surface of the lower test mold mounting plate 27, the upper end of the lower locking seat 3 is provided with a pin hole A3-1, the upper locking seat 12 is in an inverted U shape, the upper end of the lower locking seat 3 can be inserted between two side walls of the U shape, and two side walls of the U shape are provided with pin holes B12-1 corresponding to the pin hole A3-1; the lower part of the spline housing 9 is provided with an external thread section and a lower nut 26 in threaded connection, the driving plate 19 and the washer 21 are sleeved at the lower end of the spline housing 9, the washer 21 is positioned between the driving plate 19 and the first bearing 20 at the lower end of the bearing seat 10, the washer 21 and the driving plate 19 are pressed on the first bearing 20 at the lower end of the bearing seat 10 by the lower nut 26, and the driving plate 19 is connected with the spline housing 9 through a second key 35 in order to prevent the driving plate 19 and the spline housing 9 from rotating relatively; 6 arc grooves 19-1 are arranged on the drive plate 19; the upper end of the pin roll supporting seat 16 is connected with the lower surface of the test mould upper mounting plate 2, the lower end is provided with a shaft sleeve 17, the pin roll 15 is matched with the shaft sleeve 17 and can slide in the shaft sleeve 17, one end of the pin roll 15 is connected with a second bearing 18 which can horizontally rotate, the other end can be inserted into a pin hole A3-1 and a pin hole B12-1, the second bearing 18 can roll along the groove wall of an arc groove 19-1 on a driving plate 19, in the embodiment, the second bearing 18 adopts an external thread type bearing, and the thread section of the external thread type bearing is connected in the thread hole at one end of the pin; the upper locking seat 12 is provided with a rotation-stopping screw 14, the pin shaft 15 is correspondingly provided with a guide groove 13, and the rotation-stopping screw 14 extends into the guide groove 13 and can slide in the guide groove 13.
Referring to fig. 2, 6 and 7, in this example, 4 sets of test mold mounting plates are provided, each set of test mold mounting plates includes a test mold upper mounting plate 2 and a test mold lower mounting plate 27, a test mold 31 is disposed between the test mold upper mounting plate 2 and the test mold lower mounting plate 27, the test mold 31 is provided with 4 layers from top to bottom, and the layers are respectively disposed on the 4 sets of test mold mounting plates, but in the first set of test mold mounting plates, the test mold lower mounting plate 27 is replaced by an upper working table 32, and the upper portion of the test mold upper mounting plate 2 of the uppermost set of test mold mounting plates is further provided with a secondary top plate 28 for mounting a test mold mounting plate locking device of the uppermost layer; the upper mounting plate 2 of the test mould on each layer is connected with the lower mounting plate 27 of the test mould on the upper layer into a whole by bolts, a supporting sleeve 30 is arranged between the upper mounting plate 2 of the test mould and the lower mounting plate 27 of the test mould on the upper layer, and the supporting sleeve 30 corresponds to the position of the test mould 31 so as to resist the axial force applied to the test mould mounting plate by the test mould 31 during the test and cause the deformation of the test mould mounting plate.
The spline shaft is provided with 4 sections of optical shaft sections 8-1, each section of optical shaft section 8-1 corresponds to one group of test mold mounting plates and spline housings 9, and the length of each section of optical shaft section 8-1 is slightly greater than that of the corresponding spline housing 9. Taking the first layer of test mold 31 as an example, when the piston rod of the cylinder 24 extends to push the dial ring 4 to rotate, the spline housing 9 is driven to rotate by an angle of half spline teeth, the external spline on the spline shaft is opposite to the internal spline teeth on the spline housing 9, the pin shaft 15 is not inserted into the pin hole a3-1 and the pin hole B12-1 of the locking seat (see fig. 9), the lifting driving device drives the lifting column 8 to ascend, the test mold mounting plate 2 on the first layer of test mold and the test mold mounting plates above the mounting plate are driven to ascend, the test mold 31 on the first layer is opened, and at this time, the operations of loading and unloading of a test piece, checking of a sealing device and the like can.
After the test piece is installed and the sealing device is checked, the lifting driving device drives the lifting column 8 to descend to drive the mounting plate 2 on the test mold of the first layer and the test mold mounting plates above the mounting plate to descend so as to close the mold, and at the moment, the first section of smooth shaft section 8-1 on the spline shaft and the spline housing 9 corresponding to the first section of smooth shaft section are at the same height; then the control device starts the air cylinder 24 of the first layer of test mold mounting plate locking device to work, a piston rod of the air cylinder 24 retracts to pull the shifting ring 4 to rotate, the spline housing 9 is driven to rotate by a half spline tooth angle, when the external spline teeth on the spline shaft are opposite to the internal spline grooves on the spline housing 9, the lifting driving device can drive the lifting column 8 to lift and fall, and the lifting column penetrates through the spline housing 9, so that the operation on molds on other layers of test mold mounting plates is not influenced; in the process that a piston rod of the air cylinder 24 retracts to pull the shifting ring 4 to rotate and drive the spline housing 9 to rotate, the driving plate 19 connected to the lower end of the spline housing 9 rotates simultaneously, the arc-shaped groove 19-1 on the driving plate 19 drives the second bearing 18 at one end of the pin shaft 15 to roll along the groove wall of the arc-shaped groove 19-1 to drive the pin shaft 15 to slide along the shaft sleeve 17 on the pin shaft supporting seat 16, the other end of the pin shaft 15 is gradually inserted into the pin hole A3-1 and the pin hole B12-1 of the locking seat (see fig. 8), and the test mold 31 of the first layer is locked between the test mold upper mounting plate 2 and the test mold. The control system can then begin the water penetration test of the test piece according to the set test program.
The control system, the water pressure providing mechanism and the air source are arranged on the lower workbench 33, and the control system controls the air cylinder 24 to act through the electromagnetic valve, which are all the prior art. The pretreated test piece is placed in a test mold 31 of a concrete impermeability instrument, the lower part of the test mold 31 is connected with a water pressure providing mechanism, the water pressure providing mechanism comprises a pressure chamber, the pressure chamber is connected with a water tank through a pipeline, the water tank is connected with a water pump, a valve is arranged in the pipeline, the valve and the water pump are controlled by a control system, and water in the pressure chamber is provided for the test mold 31 through the pipeline.
In the description of the present invention, it should be noted that the terms "left", "right", "front", "back", "upper", "lower", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and the above terms are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.
Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are intended to be inclusive and mean, for example, that they may be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.
In addition to the technical features described in the specification, the technology is known to those skilled in the art.
The above embodiments are only specific examples of the present invention, which is not intended to limit the present invention in any way, and any person skilled in the art may modify or modify the technical details disclosed above and equally vary from the equivalent embodiments. However, any simple modification, equivalent change and modification of the above embodiments according to the technical essence of the present invention should fall within the scope of protection of the present invention without departing from the technical principle of the present invention.
Claims (5)
1. The utility model provides a concrete anti-permeability apparatus, includes lift post, lift drive arrangement, at least two sets of examination mould mounting panels, examination mould mounting panel locking device and examination mould locking device, characterized by: the lifting column is a spline shaft, a spline housing is arranged on the spline shaft, and an external spline on the spline shaft is meshed with an internal spline on the spline housing, so that the spline shaft can slide in the spline housing; the mould mounting panel locking device that tries mould includes quantity and the corresponding spline housing of group's number of trying the mould mounting panel, set up in the epaxial smooth shaft section of integral key, drive spline housing pivoted device, the spline housing rotates to be connected on trying the mould mounting panel, when the spline housing is located the epaxial smooth shaft section of integral key, drive spline housing pivoted device makes the spline housing rotate the angle of half spline tooth, the epaxial external splines of integral key is relative with the internal spline tooth on the spline housing, make the integral key shaft can not slide in the spline housing.
2. The concrete impermeability test instrument of claim 1, wherein: the test mounting plate comprises a test upper mounting plate and a test lower mounting plate, the drive spline housing rotating device comprises a bearing seat, a shifting ring and an air cylinder, the test upper mounting plate and the test lower mounting plate are respectively provided with a central through hole, the lower end of the bearing seat is connected with the test upper mounting plate, the upper end of the bearing seat is connected with the test lower mounting plate on the upper layer, the outer side wall of the spline housing is rotatably connected in the bearing seat through a first bearing, the inner hole of the spline housing can rotate around the optical axis on the spline shaft, the shifting ring is connected to the upper end of the spline housing, convex lugs are arranged on the outer circumference of the shifting ring, the air cylinder is mounted on the test lower mounting plate on the upper layer, the rod end of the air cylinder is hinged with the lugs on the shifting ring, the piston rod of the air cylinder flexibly.
3. The concrete impermeability test instrument of claim 2, wherein: the test mold locking device comprises a test mold locking device,
each group of locking seats comprises an upper locking seat fixed on the lower surface of the upper mounting plate of the test mold and a lower locking seat fixed on the upper surface of the lower mounting plate of the test mold, the upper end of the lower locking seat is provided with a pin hole A, the upper locking seat is in an inverted U shape, the upper end of the lower locking seat can be inserted between two side walls of the U shape, and the two side walls of the U shape are provided with pin holes B corresponding to the pin holes A;
the drive plate is connected with the lower end of the spline housing, at least two arc-shaped grooves are arranged on the drive plate,
the upper end of the pin roll supporting seat is connected with the lower surface of the upper mounting plate of the test mould, the lower end of the pin roll supporting seat is provided with a shaft sleeve,
the pin shaft is matched with the shaft sleeve and can slide in the shaft sleeve, one end of the pin shaft is connected with a second bearing which can horizontally rotate, the other end of the pin shaft can be inserted into the pin hole A and the pin hole B, and the second bearing can roll along the groove wall of the arc-shaped groove on the drive plate;
when the device for driving the spline sleeve to rotate drives the spline sleeve to rotate by an angle of half spline teeth, and an external spline on the spline shaft is opposite to internal spline teeth on the spline sleeve, the pin shaft is not inserted into the pin hole A and the pin hole B of the locking seat, and the lifting driving device drives the lifting column to lift and drive the mounting plate on the test mold to lift;
when the device for driving the spline sleeve to rotate drives the spline sleeve to rotate by an angle of half spline teeth, and the outer spline teeth on the spline shaft face the inner spline grooves on the spline sleeve, the pin shaft is inserted into the pin hole A and the pin hole B of the locking seat; the lifting driving device can drive the lifting column to lift and fall and penetrate through the spline sleeve.
4. The concrete impermeability test instrument of claim 2, wherein: and a support sleeve is arranged between the test mold upper mounting plate and the test mold lower mounting plate on the upper layer.
5. The concrete impermeability test instrument of claim 3, wherein: and the upper locking seat is provided with a rotation stopping screw, the pin shaft is correspondingly provided with a guide groove, and the rotation stopping screw extends into the guide groove and can slide in the guide groove.
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