CN204154558U - For making the die trial of the tailing-filled slip test block in mine - Google Patents

Abstract

The utility model discloses a kind of die trial for making the tailing-filled slip test block in mine; comprise the main die trial for the tailing-filled slip test block of shaping mine; die trial also comprises the auxiliary guards mould watering fluence for increasing test block; auxiliary guards mould is located at main die trial top; the auxiliary cast chamber of auxiliary guards mould is arranged with the main cast chamber of main die trial is corresponding up and down, is provided with the integrated positioning mechanism of the location that interfixes between main die trial and auxiliary guards mould.Main die trial increases auxiliary guards mould, fluence is watered with what increase the tailing-filled slip in mine, in test block manufacturing process, mine tailing-filled slip disposal pouring in die trial completes, without the need to carrying out benefit slurry, reduce the labor capacity of repeatedly mending slurry, improve the intensity of test block measuring accuracy of the tailing-filled slip in mine.Mainly be applicable to large, that the slip that bleeding shrinks easily the occurs reference block of the slump make.

Description

For making the die trial of the tailing-filled slip test block in mine

Technical field

The utility model relates to tailings obturator proving installation field, mine, especially, relating to a kind of die trial for making the tailing-filled slip test block in mine, being specifically related to a kind of for making mine tailing-filled material compressive strength test and the one-time formed standard die trial for the cube specimen that shrinks greatly.

Background technology

Mine is tailing-filled is the key areas that stowing method is dug up mine, and is the important channel of mine solid waste recycling, is to solve mill tailings store up and extenuate the important measures of environmental problem.Mine is tailing-filled, has that technological process is simple, filling quality good, filling cost is low, stowing capacity is large, manages numerous advantage such as simple, adopted by increasing mine.

Filling is the core link of the method for mining by the way of filling, and filling cost accounts for more than 30 ~ 50% of mining direct cost, and strength of filling mass design is the guarantee of method of mining by the way of filling safety, low consumption back production mineral resources, therefore, determines that the strength of filling mass of economical rationality is most important.And to carry out strength of filling mass Optimum Experiment be key link before filling, strength of filling mass Optimum Experiment by inspection filling slurry strength character, for the design of method of mining by the way of filling Strength of backfill provides foundation, to ensure Quality of filling body.Therefore, pour into a mould test block, test the important content that the strength character of obturation is method of mining by the way of filling research and routine work.

Because the filling slurry that mine is tailing-filled generally will carry out the conveying growing distance, so filling slurry mass concentration lower (mostly between 60 ~ 75%, part mine is lower); Simultaneously due to the material singularity of the tailing-filled filling slurry in mine, its slump is at 25cm or more, General Requirements can Self-leveling, filling aggregate porosity is large, volumetric concentration is low, and when moulding by casting, easily generation bleeding shrinks, and (shrink rate about 10% ~ 35%, even larger), can not die trial be full of after test block cast once shrinks.Therefore, test block cast needs repeatedly to mend slurry, just can reach briquette marking alignment request, but the bleeding settling velocity of slip differs, and test block cast labor capacity is large, expends man-hour.Most important, test block is mended slurry and must be completed before slip initial set, but in die trial, the slip presetting period of different ratio judges that difficulty is large, in addition, the test block of repeatedly pouring into a mould layering in the height direction, after form removal, the easy absciss layer breakage of test block etc., affect the precision of intensity of test block test; Even cannot the test block of production standard, cause test meaningless.Therefore, when filling slurry concentration is lower, when the bleeding rate that shrinks is larger, existing die trial cannot make filling slurry reference block.

Utility model content

The utility model object is to provide a kind of die trial for making the tailing-filled slip test block in mine, with solve the existing die trial filling slurry tailing-filled in mine make test block time, need to complete before slip initial set repeatedly to pour into a mould, because filling slurry bleeding settling velocity differs, labor capacity is large, difficulty greatly, repeatedly pours into a mould easy layering, the technical matters that the making that cannot meet reference block requires to cause test block to pour into a mould.

For achieving the above object, the technical solution adopted in the utility model is as follows:

A kind of die trial for making the tailing-filled slip test block in mine; comprise the main die trial for the tailing-filled slip test block of shaping mine; die trial also comprises the auxiliary guards mould watering fluence for increasing test block; auxiliary guards mould is located at main die trial top; the auxiliary cast chamber of auxiliary guards mould is arranged with the main cast chamber of main die trial is corresponding up and down, is provided with the integrated positioning mechanism of the location that interfixes between main die trial and auxiliary guards mould.

Further, main die trial comprises bed die, two pieces of master moulds and at least two pieces of main dividing plates, and two pieces of master mode spacings are arranged and are erected on bed die, and main dividing plate is fixed between two pieces of master moulds along the plate face vertical direction of master mould; Master mould encloses with the main dividing plate being located at periphery and forms main cast chamber, and main cast chamber is separated into decile chamber by the main dividing plate be located in main cast chamber.

Further, auxiliary guards mould comprises two pieces of auxiliary side forms and two pieces of auxiliary transverse modes; Two pieces of auxiliary side forms positioned opposite and two pieces of auxiliary transverse modes positioned opposite enclose to be formed auxiliaryly pours into a mould chamber.

Further, master mould is identical with the horizontal cross section dimension of auxiliary side form; And/or main dividing plate is identical with the horizontal cross section dimension of auxiliary transverse mode.

Further, auxiliary cast chamber is identical with the horizontal cross section dimension in main cast chamber with the faying face horizontal cross section dimension of contact site, described main cast chamber.

Further, auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in auxiliary cast chamber is towards vertically arranging; Or auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in auxiliary cast chamber is arranged towards along the direction favouring surface level; Or auxiliary cast chamber horizontal cross section dimension reduces from top to bottom gradually.

Further, the lower surface of auxiliary guards mould and the upper surface of main die trial are fitted and are arranged.

Further, integrated positioning mechanism comprises main die trial detent mechanism, and main die trial detent mechanism comprises the first hinged support be fixed on bed die, the first slide bar be hinged on the first hinged support, the first positioning lock be slidably connected on the first slide bar, the first setscrew nut and is opened in the first locating slot of master template end; The two ends of the first positioning lock are extended with the first pilot pin respectively to first locating slot at two ends; By installing the first setscrew nut on the first pilot pin, to be held between the first positioning lock and the first setscrew nut by master die clamp, thus realize the location between two pieces of master moulds; By installing the first setscrew nut at the free end of the first slide bar, the first positioning lock is locked from the top of the first positioning lock, first pilot pin at the first positioning lock two ends locks master mould downwards in the first locating slot of master mould, thus realizes the location between master mould and bed die.

Further, integrated positioning mechanism also comprises auxiliary guards die positioning mechanism; Auxiliary guards die positioning mechanism comprises the second hinged support be fixed on bed die, the second slide bar be hinged on the second hinged support, the second positioning lock be slidably connected on the second slide bar, the second setscrew nut and is opened in the second locating slot of secondary side template end; The two ends of the second positioning lock are extended with the second pilot pin respectively to second locating slot at two ends; By installing the second setscrew nut on the second pilot pin, secondary side die clamp is held between the second positioning lock and the second setscrew nut, thus realizes the location between two pieces of auxiliary side forms; By installing the second setscrew nut at the free end of the second slide bar, the second positioning lock is locked from the top of the second positioning lock, second pilot pin auxiliary side form of locking downwards in the second locating slot of auxiliary side form at the second positioning lock two ends, thus realize the location of asking of auxiliary side form and bed die.

Further, the first slide bar and the second slide bar connect as one; And/or first positioning lock and the second positioning lock connect as one; And/or first hinged support and the second hinged support connect as one.

The utility model has following beneficial effect:

The utility model is for making the die trial of the tailing-filled slip test block in mine, main die trial increases auxiliary guards mould, fluence is watered with what increase the tailing-filled slip in mine, the bleeding produced in manufacturing process for solving mine tailing-filled slip test block body shrinks phenomenon, eliminates bleeding and to shrink the impact that phenomenon produces production standard test block; In test block manufacturing process, mine tailing-filled slip disposal pouring in die trial completes, without the need to carrying out benefit slurry, greatly reduce the labor capacity of repeatedly mending slurry, the material singularity that can effectively solve due to the tailing-filled slip in mine needs repeatedly to mend the drawback of slurry, avoid producing the problem causing test block layering owing to repeatedly mending slurry, avoid mending slurry and cause the problem of mending slurry and exceeding the presetting period not in time, substantially increase the intensity of test block measuring accuracy of the tailing-filled slip in mine.The utility model die trial is mainly applicable to large, that the slip that bleeding shrinks easily the occurs reference block of the slump and makes.

Except object described above, feature and advantage, the utility model also has other object, feature and advantage.Below with reference to figure, the utility model is described in further detail.

Accompanying drawing explanation

The accompanying drawing forming a application's part is used to provide further understanding of the present utility model, and schematic description and description of the present utility model, for explaining the utility model, is not formed improper restriction of the present utility model.In the accompanying drawings:

Fig. 1 is the structural representation of the die trial for making the tailing-filled slip test block in mine of the utility model preferred embodiment;

Fig. 2 is the structural representation of the main die trial of the utility model preferred embodiment.

Marginal data:

1, main die trial; 101, bed die; 102, master mould; 103, main dividing plate; 2, auxiliary guards mould; 201, auxiliary side form; 202, auxiliary transverse mode; 3, integrated positioning mechanism; 301, main die trial detent mechanism; 3011, the first hinged support; 3012, the first slide bar; 3013, the first positioning lock; 3014, the first setscrew nut; 3015, the first locating slot; 302, auxiliary guards die positioning mechanism; 3021, the second hinged support; 3022, the second slide bar; 3023, the second positioning lock; 3024, the second setscrew nut; 3025, the second locating slot; 4, the first pilot pin; 5, the second pilot pin.

Embodiment

Below in conjunction with accompanying drawing, embodiment of the present utility model is described in detail, but the utility model can by the multitude of different ways that limits and cover implement.

Fig. 1 is the structural representation of the die trial for making the tailing-filled slip test block in mine of the utility model preferred embodiment; Fig. 2 is the structural representation of the main die trial of the utility model preferred embodiment.

As shown in Figure 1; the die trial for making the tailing-filled slip test block in mine of the present embodiment; comprise the main die trial 1 for the tailing-filled slip test block of shaping mine; die trial also comprises the auxiliary guards mould 2 watering fluence for increasing test block; auxiliary guards mould 2 is located at main die trial 1 top; the auxiliary cast chamber of auxiliary guards mould 2 is arranged with the main cast chamber of main die trial 1 is corresponding up and down, is provided with the integrated positioning mechanism 3 of the location that interfixes between main die trial 1 and auxiliary guards mould 2.The utility model is for making the die trial of the tailing-filled slip test block in mine, main die trial 1 increases auxiliary guards mould 2, fluence is watered with what increase the tailing-filled slip in mine, the bleeding produced in manufacturing process for solving mine tailing-filled slip test block body shrinks phenomenon, eliminates bleeding and to shrink the impact that phenomenon produces production standard test block; In test block manufacturing process, mine tailing-filled slip disposal pouring in die trial completes, without the need to carrying out benefit slurry, greatly reduce the labor capacity of repeatedly mending slurry, the material singularity that can effectively solve due to the tailing-filled slip in mine needs repeatedly to mend the drawback of slurry, avoid producing the problem causing test block layering owing to repeatedly mending slurry, avoid mending slurry and cause the problem of mending slurry and exceeding the presetting period not in time, substantially increase the intensity of test block measuring accuracy of the tailing-filled slip in mine.The utility model die trial is mainly applicable to large, that the slip that bleeding shrinks easily the occurs reference block of the slump and makes.

As depicted in figs. 1 and 2, in the present embodiment, main die trial 1 comprises bed die 101, two pieces of master moulds 102 and at least two pieces of main dividing plates 103, two pieces of master mould 102 intervals are arranged and are erected on bed die 101, and main dividing plate 103 is fixed between two pieces of master moulds 102 along the plate face vertical direction of master mould 102.Preferably, be parallel to each other between multiple main dividing plate 103 and equidistantly arrange.Preferably, be parallel to each other between two main dividing plates 103 and equidistantly arrange.Master mould 102 encloses with the main dividing plate 103 being located at periphery and forms main cast chamber, and main cast chamber is separated into decile chamber by the main dividing plate 103 be located in main cast chamber.Preferably, master mould 102 also can adopt at least one in straight plate, L shaped plate, trough plate.Preferably, the quantity of bed die 101, master mould 102 and main dividing plate 103 can be selected as required.Preferably, master mould 102 is provided with the detent mechanism of locating for main dividing plate 103, and detent mechanism can be locating slot, positioning sleeve etc.Preferably, bed die 101 is provided with the detent mechanism of locating for master mould 102 and/or main dividing plate 103, detent mechanism can be locating slot, positioning sleeve etc.Main die trial 1 is the mould of shaping reference block, needs to select different connecting methods according to the size of actual test block, the shaping reference block of convenient making.

As shown in Figure 1, in the present embodiment, auxiliary guards mould 2 comprises two pieces of auxiliary side forms 201 and two pieces of auxiliary transverse modes 202; Two pieces of auxiliary side forms 201 positioned opposite and two pieces of auxiliary transverse modes 202 positioned opposite enclose to be formed auxiliaryly pours into a mould chamber.Preferably, auxiliary side form 201 or auxiliary transverse mode 202 also can adopt at least one in straight plate, L shaped plate, trough plate.Preferably, the quantity of auxiliary side form 201 or auxiliary transverse mode 202 can be selected as required.Preferably, master mould 102 is provided with the detent mechanism of locating for auxiliary side form 201 and/or auxiliary transverse mode 202, and detent mechanism can be locating slot, positioning sleeve, positioning link etc.Auxiliary guards mould 2 is the auxiliary mould of shaping reference block, according to the height making the different auxiliary guards mould 2 of the material different choice of test block, with assistant formation reference block, eliminates the impact that material causes because bleeding shrinks.

As depicted in figs. 1 and 2, in the present embodiment, master mould 102 is identical with the horizontal cross section dimension of auxiliary side form 201; And/or main dividing plate 103 is identical with the horizontal cross section dimension of auxiliary transverse mode 202.Master mould 102 is facilitated to splice with the laminating of auxiliary side form 201.

As depicted in figs. 1 and 2, in the present embodiment, auxiliary cast chamber is identical with the horizontal cross section dimension in main cast chamber with the faying face horizontal cross section dimension of contact site, main cast chamber.Convenient auxiliary cast chamber is docked with main cast chamber, facilitates slip directly to enter main cast chamber from auxiliary cast chamber, reduces the probability of slip seepage.

In the present embodiment, auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in auxiliary cast chamber is towards vertically arranging.Facilitate structure manufacture and assembled.Auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in auxiliary cast chamber is arranged towards along the direction favouring surface level.Understand during cast and flow into wall, convenient cast, the convenient speed controlling cast.Auxiliary cast chamber horizontal cross section dimension reduces from top to bottom gradually.The slip capacity in auxiliary cast chamber can be improved, also can reduce the material usage of auxiliary side form 201 simultaneously, thus reduce the cost of manufacture of mould.

In the present embodiment, the lower surface of auxiliary guards mould 2 and the upper surface of main die trial 1 are fitted and are arranged.Convenient auxiliary cast chamber is docked with main cast chamber, facilitates slip directly to enter main cast chamber from auxiliary cast chamber, reduces the probability of slip seepage.

In the present embodiment, integrated positioning mechanism 3 comprises main die trial detent mechanism 301, and main die trial detent mechanism 301 comprises the first hinged support 3011 be fixed on bed die 101, the first slide bar 3012 be hinged on the first hinged support 3011, is slidably connected at the first positioning lock 3013, first setscrew nut 3014 on the first slide bar 3012 and is opened in the first locating slot 3015 of master mould 102 plate end.The two ends of the first positioning lock 3013 are extended with the first pilot pin 4 respectively to first locating slot 3015 at two ends.By installing the first setscrew nut 3014 on the first pilot pin 4, to be clamped in by master mould 102 between first positioning lock 3013 and the first setscrew nut 3014, thus realize the location between two pieces of master moulds 102.By installing the first setscrew nut 3014 at the free end of the first slide bar 3012, the first positioning lock 3013 is locked from the top of the first positioning lock 3013, first pilot pin 4 at the first positioning lock 3013 two ends locks master mould 102 downwards in the first locating slot 3015 of master mould 102, thus realizes the location between master mould 102 and bed die 101.By the first hinged support 3011, location is fixed to whole main die trial detent mechanism 301.By the slidable adjustment of the first positioning lock 3013 on the first slide bar 3012, be locked on two pieces of master moulds 102 be arranged in parallel or in the first locating slot 3015 of two pieces of master moulds 102 be arranged in parallel to select the latch-up structure at the first positioning lock 3013 two ends.The first pilot pin 4 that latch-up structure adopts the first setscrew nut 3014 and is located at the first positioning lock 3013 end is connected, and is locked in by master mould 102 between first setscrew nut 3014 and the first positioning lock 3013.By the first setscrew nut 3014 being connected to the first slide bar 3012 end, downward pressure is applied to the first positioning lock 3013, be equipped with latch-up structure simultaneously and lock while master mould 102 two ends, carry out the mutual location between master mould 102 and bed die 101.

In the present embodiment, integrated positioning mechanism 3 also comprises auxiliary guards die positioning mechanism 302; Auxiliary guards die positioning mechanism 302 comprises the second hinged support 3021 be fixed on bed die 101, the second slide bar 3022 be hinged on the second hinged support 3021, is slidably connected at the second positioning lock 3023, second setscrew nut 3024 on the second slide bar 3022 and is opened in the second locating slot 3025 of auxiliary side form 201 plate end; The two ends of the second positioning lock 3023 are extended with the second pilot pin 5 respectively to second locating slot 3025 at two ends; By installing the second setscrew nut 3024 on the second pilot pin 5, auxiliary side form 201 is clamped between the second positioning lock 3023 and the second setscrew nut 3024, thus realizes the location between two pieces of auxiliary side forms 201; By installing the second setscrew nut 3024 at the free end of the second slide bar 3022, the second positioning lock 3023 is locked from the top of the second positioning lock 3023, second pilot pin 5 at the second positioning lock 3023 two ends from the auxiliary side form 201 of locking downwards in the second locating slot 3025 of auxiliary side form 201, thus realizes auxiliary location between side form 201 and bed die 101.By the second hinged support 3021, location is fixed to whole auxiliary guards die positioning mechanism 302.Be locked on two pieces of auxiliary side forms 201 be arranged in parallel or in the second locating slot 3025 of two pieces of auxiliary side forms 201 be arranged in parallel to select the latch-up structure at the second positioning lock 3023 two ends by the slidable adjustment of the second positioning lock 3023 on the second slide bar 3022.The second pilot pin 5 that latch-up structure adopts the second setscrew nut 3024 and is located at the second positioning lock 3023 end is connected, and is locked in by auxiliary side form 201 between second setscrew nut 3024 and the second positioning lock 3023.By the second setscrew nut 3024 being connected to the second slide bar 3022 end, downward pressure is applied to the second positioning lock 3023, be equipped with latch-up structure simultaneously and lock while auxiliary side form 201 two ends, carry out the mutual location between auxiliary side form 201 and bed die 101.

In the present embodiment, the first slide bar 3012 and the second slide bar 3022 connect as one; And/or first positioning lock 3013 and the second positioning lock 3023 connect as one; And/or first hinged support 3011 and the second hinged support 3021 connect as one.By arranging disjunctor assembly, facilitate the overall stationary positioned between main die trial 1 and auxiliary guards mould 2.Preferably, the cutting blade for cutting the unnecessary slip in main die trial 1 is also provided with between main die trial 1 and auxiliary guards mould 2.For the unnecessary slip excision on main die trial 1 surface.

In the present embodiment, main die trial 1 and/or auxiliary guards mould 2 are provided with for the shaping vibrating handle of hand-held slip jolt ramming.The convex configuration for the shaping vibration force of amplification slip jolt ramming is provided with bottom bed die 101.For improving the vibrating effect of die trial, accelerate the vibratory compaction speed of slip.Main die trial 1 and/or auxiliary guards mould 2 are provided with the vibration amplification shell fragment for amplification die trial vibrating effect.Utilize the collaborative resonance of vibration amplification shell fragment, increase the vibrating effect of die trial, accelerate the vibratory compaction speed of slip.

During enforcement, the utility model provides a kind of special die trial of filling slurry compressive strength test block forming; Die trial material can adopt the requirement meeting die trial and make, any material with certain rigidity is made, and can make plastics, iron, steel etc.The feature of die trial is that adding die trial protects die sleeve (auxiliary guards mould 2), adds the volume of die trial, can hold more slip, still can fill bottom die trial, thus reach one-time formed object after the sedimentation of filling slurry bleeding.

This protect that mould can form for any one material or structure can improve once-cast volume, the special model volume that protects increased is greater than the volume that bleeding shrinks, thus after playing cast, test block is one-time formed protects mould utensil.

The utility model is the weak point of avoiding existing test block forming die trial to exist and the difficult problem being difficult to make low concentration and the rate test specimen that shrinks greatly, provide a kind of be easy to operation, test efficiency high, can the tailing-filled slip cubic compressive strength test specimen die trial of one-time cast-forming.Especially, can be used for low concentration, to shrink the moulding by casting of test specimen greatly.To achieve these goals, increase die trial and protect die sleeve, protect die sleeve and play increase slip casting amount, die trial cover active volume is greater than the maximum volume that shrinks of slip, and concrete enforcement can customize according to the characteristic of different tests consumptive material.The inner chamber of die trial cover overlaps completely with the inner chamber of die trial, does not establish dividing plate.

Main die trial 1 is made up of two pieces of master moulds 102 and four pieces of main dividing plates 103, two master moulds 102 are fixed by bolt (first setscrew nut 3014 and the first pilot pin 4), are then fixed on bed die 101 by eye bolt (first setscrew nut 3014 and the first slide bar 3012).After die trial assembles, assembling die trial cover (auxiliary guards mould 2) again, die trial cover (auxiliary guards mould 2) is made up of two pieces of auxiliary side forms 201 and two pieces of auxiliary transverse modes 202, two pieces of auxiliary side forms 201 are fixed by bolt (second setscrew nut 3024 and the second pilot pin 5), and then by bolt (second setscrew nut 3024 and the second slide bar 3022), die trial cover (auxiliary guards mould 2) is fixed on bed die 101, the relative position of die trial cover (auxiliary guards mould 2) with main die trial 1 is positioned simultaneously.

Embodiment:

(1) encapsulants such as butter are adopted to smear the outer seam of main die trial 1 and auxiliary guards mould 2, first main die trial 1 (as Fig. 2) and auxiliary guards mould 2 (as Fig. 1) are assembled, the machine oil of main die trial 1 and the inner brushing thin layer of auxiliary guards mould 2 or release agent.

(2) fill main die trial 1 and auxiliary guards mould 2 by disposable for tailing slurry that mixing is good, according to different denseness, adopt manually plug and pound or shaking table to carry out jolt ramming shaping.

(3) after test specimen initial set, after slip no longer shrinks, auxiliary guards mould 2 is removed, the tailing slurry exceeding main die trial 1 part to be scraped off and floating along die trial end face.

(4) static maintenance (being generally no more than 2d) under the environment of temperature 20 ± 5 DEG C after test specimen making, when test specimen reaches certain intensity, test specimen is numbered, then removes main die trial 1, test specimen is put into the indoor maintenance of standard curing, so far complete the making of test specimen.

(5) maintenance test specimen reaches and tests the length of time, carries out intensity test.

Filling slurry cubic compressive strength test specimen one-time cast-forming can be realized.Do not need repeatedly to carry out slip casting, effectively can improve the efficiency of work, reduce labour intensity; Solving because repeatedly pouring into a mould the test block layering caused, improving filling slurry compressive strength test block forming quality, for Measurement accuracy filling slurry compressive strength lays the foundation; The test block one-shot forming of low concentration filling slurry and making can be realized.

Increase the test specimen cast that the technical thought of protecting die sleeve can be applied to other test of tailing-filled performance test, as tension, anti-folding etc. and the disposal pouring of test specimen of shrinking greatly shaping, its key point is that the once-cast volume protecting die sleeve (auxiliary guards mould 2) and increase should be greater than the volume shunk.Apply the theory of this technology, existing die trial can be improved, the basis of die trial is set up die trial cover (auxiliary guards mould 2), fixation (fixation can adopt web member, holder, lock piece, non return part etc.) is taked die trial cover (auxiliary guards mould 2) and die trial (main die trial 1) to be fixed, mortar leakage prevention.

The foregoing is only preferred embodiment of the present utility model, be not limited to the utility model, for a person skilled in the art, the utility model can have various modifications and variations.All within spirit of the present utility model and principle, any amendment done, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.

Claims (10)

1., for making a die trial for the tailing-filled slip test block in mine, comprise the main die trial (1) for the tailing-filled slip test block of shaping mine,

It is characterized in that,

Described die trial also comprises the auxiliary guards mould (2) watering fluence for increasing test block,

Described auxiliary guards mould (2) is located at described main die trial (1) top,

The auxiliary cast chamber of described auxiliary guards mould (2) is arranged with the main cast chamber of described main die trial (1) is corresponding up and down,

The integrated positioning mechanism (3) of the location that interfixes is provided with between described main die trial (1) and described auxiliary guards mould (2).

2. the die trial for making the tailing-filled slip test block in mine according to claim 1, is characterized in that,

Described main die trial (1) comprises bed die (101), two pieces of master moulds (102) and at least two pieces of main dividing plates (103),

Two pieces of described master mould (102) intervals are arranged and are erected on described bed die (101),

Described main dividing plate (103) is fixed between two pieces of described master moulds (102) along the plate face vertical direction of described master mould (102);

Described master mould (102) encloses with the described main dividing plate (103) being located at periphery and forms described main cast chamber,

Described main cast chamber is separated into decile chamber by the described main dividing plate (103) be located in described main cast chamber.

3. the die trial for making the tailing-filled slip test block in mine according to claim 2, is characterized in that,

Described auxiliary guards mould (2) comprises two pieces of auxiliary side forms (201) and two pieces of auxiliary transverse modes (202);

Two pieces of described auxiliary side forms (201) positioned opposite enclose with two pieces of described auxiliary transverse modes (202) positioned opposite and form described auxiliary cast chamber.

4. the die trial for making the tailing-filled slip test block in mine according to claim 3, is characterized in that,

Described master mould (102) is identical with the horizontal cross section dimension of described auxiliary side form (201); And/or

Described main dividing plate (103) is identical with the horizontal cross section dimension of described auxiliary transverse mode (202).

5. the die trial for making the tailing-filled slip test block in mine according to claim 3, is characterized in that, described auxiliary cast chamber is identical with the horizontal cross section dimension in main cast chamber with the faying face size of contact site, described main cast chamber.

6. the die trial for making the tailing-filled slip test block in mine according to claim 5, is characterized in that,

Described auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in described auxiliary cast chamber is towards vertically arranging; Or

Described auxiliary cast chamber horizontal cross section dimension is identical from top to bottom, and the cast opening in described auxiliary cast chamber is arranged towards along the direction favouring surface level; Or

Described auxiliary cast chamber horizontal cross section dimension reduces from top to bottom gradually.

7. the die trial for making the tailing-filled slip test block in mine according to claim 5, is characterized in that, the lower surface of described auxiliary guards mould (2) and the upper surface of described main die trial (1) are fitted and arranged.

8. the die trial for making the tailing-filled slip test block in mine according to any one of claim 3 to 7, is characterized in that,

Described integrated positioning mechanism (3) comprises main die trial detent mechanism (301),

Described main die trial detent mechanism (301) comprises the first hinged support (3011) be fixed on described bed die (101), the first slide bar (3012) be hinged on described first hinged support (3011), the first positioning lock (3013) be slidably connected on described first slide bar (3012), the first setscrew nut (3014) and be opened in first locating slot (3015) of described master mould (102) plate end;

The two ends of described first positioning lock (3013) are extended with the first pilot pin (4) respectively to described first locating slot (3015) at two ends;

By above installing described first setscrew nut (3014) described first pilot pin (4), described master mould (102) to be clamped between described first positioning lock (3013) and described first setscrew nut (3014), thus realize the location between two pieces of described master moulds (102);

By the free end described first slide bar (3012), described first setscrew nut (3014) is installed, from described first positioning lock (3013) of top locking of described first positioning lock (3013), described first pilot pin (4) at described first positioning lock (3013) two ends locks described master mould (102) downwards in described first locating slot (3015) of described master mould (102), thus realizes the location between described master mould (102) and described bed die (101).

9. the die trial for making the tailing-filled slip test block in mine according to claim 8, is characterized in that,

Described integrated positioning mechanism (3) also comprises auxiliary guards die positioning mechanism (302);

Described auxiliary guards die positioning mechanism (302) comprises the second hinged support (3021) be fixed on described bed die (101), the second slide bar (3022) be hinged on described second hinged support (3021), the second positioning lock (3023) be slidably connected on described second slide bar (3022), the second setscrew nut (3024) and be opened in second locating slot (3025) of described auxiliary side form (201) plate end;

The two ends of described second positioning lock (3023) are extended with the second pilot pin (5) respectively to described second locating slot (3025) at two ends;

By described auxiliary side form (201) being clamped between described second positioning lock (3023) and described second setscrew nut (3024) described second setscrew nut (3024) of the upper installation of described second pilot pin (5), thus realize the location between two pieces of described auxiliary side forms (201);

By the free end described second slide bar (3022), described second setscrew nut (3024) is installed, from described second positioning lock (3023) of top locking of described second positioning lock (3023),

Described second pilot pin (5) at described second positioning lock (3023) two ends locks described auxiliary side form (201) downwards in described second locating slot (3025) of described auxiliary side form (201), thus realizes the location between described auxiliary side form (201) and described bed die (101).

10. the die trial for making the tailing-filled slip test block in mine according to claim 9, is characterized in that,

Described first slide bar (3012) and described second slide bar (3022) connect as one; And/or

Described first positioning lock (3013) and described second positioning lock (3023) connect as one; And/or

Described first hinged support (3011) and described second hinged support (3021) connect as one.