CN220961090U - Cement density check out test set with temperature regulation structure - Google Patents

Abstract

The utility model relates to the technical field of cement density detection equipment, in particular to cement density detection equipment with a temperature regulation structure, which comprises a test box, wherein the front end of the test box is movably connected with a door plate, the outer wall of the door plate is embedded with a transparent plate, a detection device is arranged in the test box, the top end of the test box is embedded with a regulation mechanism, and a heat insulation plate is embedded between two adjacent groups of test boxes; the adjustment mechanism includes an electromagnetic heater body. The utility model sets up the test box and all places the checkout gear, the top inlays the electromagnetic heater main part separately at the same time, through regulating the temperature of the electromagnetic heater main part, thus heat the heated board, and raise the interface of heat and air through the heat transfer plate, the internal temperature of the quick adjustment test box, facilitate carrying on the detection of different temperatures to the different test blocks of multiunit at the same time, thus is used for data comparison, the filter screen inlays the outside of radiating end of the electromagnetic heater main part, avoid the external dust impurity to get into and absorb and influence the heat dissipation.

Description

Cement density check out test set with temperature regulation structure

Technical Field

The utility model relates to the technical field of cement density detection equipment, in particular to cement density detection equipment with a temperature adjusting structure.

Background

The density of cement is generally about 3.0-3.15 g per cubic centimeter, water vapor possibly exists in the cement under the condition of different temperatures, so that the density has a certain influence, the cement is generally detected by a Lishi method and a gas displacement method, wherein the Lishi method is mostly used, the volume of the cement with a certain weight is measured by the volume scale of the shin part of a Lishi bottle, the cement is added into the Lishi bottle filled with a certain amount of liquid medium, the liquid medium fully infiltrates cement particles, and the volume of the cement is equal to the volume of liquid discharged by the liquid medium, so that the mass per unit volume of the cement is calculated to be the density.

The cement density detection equipment with the publication number of CN213337207U comprises an equipment main body, a rubber pad is fixedly arranged at the bottom of a supporting column, a drawer is movably arranged at the front end of the equipment main body near the middle position, a handle is fixedly arranged at the middle position on the drawer, a thermometer is fixedly arranged at the left side of the top of the equipment main body, a motor is fixedly arranged at the right side of the inside of the equipment main body, a rotary table is fixedly arranged on the motor, a strong magnet is fixedly arranged in the rotary table, and a placing box is fixedly arranged at the top of the rotary table. This cement density check out test set can detect outdoor temperature through the thermometer, then the temperature that the incasement portion was placed in the contrast is unanimous, when inconsistent, opens the hot plate and to place the incasement portion and heat, when dripping into, because second spliced pole and third spliced pole and Lishi bottle are fixed vertical state, can effectively prevent that solution and cement from dripping outside the Lishi bottle or on the inner wall when dripping into.

In summary, the following technical problems exist in the prior art: in the prior art, the placing box is heated through the heating plate, but the heating plate is inconvenient to accurately adjust the temperature in the use process, and meanwhile, when the cement density is detected, the corresponding temperature is required to be adjusted according to the external temperature, and detection is required to be carried out at different temperatures simultaneously so as to facilitate better contrast data, so that the density detection equipment capable of adjusting the temperature is required, and therefore, the cement density detection equipment with the temperature adjusting structure is provided.

Disclosure of utility model

The utility model aims to provide cement density detection equipment with a temperature adjusting structure, so as to solve the problems in the background technology.

In order to solve the technical problems, the utility model adopts the following technical scheme:

The cement density detection equipment with the temperature regulation structure comprises a test box, wherein the front end of the test box is movably connected with a door plate, the outer wall of the door plate is embedded with a transparent plate, a detection device is arranged in the test box, the top end of the test box is embedded with a regulation mechanism, and a heat insulation plate is embedded between two adjacent groups of test boxes;

The adjusting mechanism comprises an electromagnetic heater main body, the electromagnetic heater main body is detachably mounted on the top end of the test box through a bolt, a filter screen is embedded on the top end of the electromagnetic heater main body, a heated plate is fixed at one end of the electromagnetic heater main body penetrating into the test box, and heat transfer plates are mounted on two sides of the bottom end of the heated plate, which are located on the detection device.

Preferably, the heated plate and the heat transfer plate are perpendicular to each other, and the heated plate and the heat transfer plate form a U-shaped structure.

Preferably, a supporting plate is fixed below the inner wall of the test box, a sliding groove is formed in the center of the supporting plate, and a supporting mechanism penetrates out of the sliding groove.

Preferably, the support carrying mechanism comprises a sliding plate, the sliding plate is connected above the support carrying plate in a sliding way through a sliding groove, the top end of the support carrying plate is provided with reserved grooves on two sides of the sliding groove, a connecting plate is arranged between the sliding plate and the support carrying plate, a plurality of rollers are embedded in positions, corresponding to the reserved grooves, of the connecting plate, a plurality of groups of damping springs are uniformly installed on the connecting plate, corresponding to the outer wall surface of the sliding plate, at equal intervals, and a telescopic rod is fixedly installed on one side of the damping springs at the top end of the connecting plate.

Preferably, the connecting plate is elastically connected with the sliding plate through a damping spring, and a sliding structure is formed between the connecting plate and the support plate through the idler wheels and the reserved grooves.

Preferably, a moving mechanism is arranged below the supporting plate and comprises a connecting plate, the connecting plate is fixedly arranged on the bottom end of the sliding plate penetrating out of the supporting plate through the sliding groove in an axial direction, the bottom end of the connecting plate is connected with a fixing plate, and an electric push rod is arranged between the fixing plate and the inner wall of the test box.

Preferably, the fixing plate forms a sliding structure with the supporting plate through the connecting plate, and forms a telescopic structure with the test box through the electric push rod.

The above description shows that the technical problems to be solved by the present application can be solved by the above technical solutions of the present application.

Meanwhile, through the technical scheme, the utility model has at least the following beneficial effects:

The utility model sets up the test box and all places the checkout gear, the top inlays the electromagnetic heater main part separately at the same time, through regulating the temperature of the electromagnetic heater main part, thus heat the heated board, and raise the interface of heat and air through the heat transfer plate, the internal temperature of the quick adjustment test box, facilitate carrying on the detection of different temperatures to the different test blocks of multiunit at the same time, thus is used for data comparison, the filter screen inlays the outside of radiating end of the electromagnetic heater main part, avoid the external dust impurity to get into and absorb and influence the heat dissipation.

According to the utility model, the sliding plate drives the detection device to slide on the support carrier plate through the sliding groove, so that the sliding plate can conveniently penetrate into the test box, the damping spring elastically pushes the connecting plate, the roller at the bottom end of the connecting plate penetrates into the reserved groove formed in the support carrier plate, the sliding smoothness of the sliding plate is improved, meanwhile, the sliding plate has certain shock absorption, and the connecting plate is supported by the telescopic rod, so that the sliding plate is prevented from being deviated due to deviation in sliding, and the detection of the detection device is influenced.

According to the utility model, the fixed plate is pushed by the electric push rod, so that the connecting plate supports the sliding plate to slide along the sliding groove on the supporting plate, the sliding plate is conveniently driven by the electric push rod to stretch and retract, the supporting detection device slides, the influence on the detection device caused by fluctuation generated during manual pushing is avoided, and meanwhile, the labor intensity is reduced.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of a heat transfer plate according to the present utility model;

FIG. 3 is a schematic view of a carrier plate structure according to the present utility model;

fig. 4 is a schematic structural view of a moving mechanism of the present utility model.

In the figure: 1. a test box; 2. a door panel; 3. a transparent plate; 4. a detection device; 5. an adjusting mechanism; 501. an electromagnetic heater body; 502. a filter screen; 503. a heated plate; 504. a heat transfer plate; 6. a thermal insulation plate; 7. a support plate; 8. a chute; 9. a supporting mechanism; 901. a sliding plate; 902. a damping spring; 903. a telescopic rod; 904. a connecting plate; 905. a roller; 906. a reserved groove; 10. a moving mechanism; 1001. a splice plate; 1002. a fixing plate; 1003. an electric push rod.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Description of the preferred embodiments

As shown in fig. 1-4, the present utility model provides a technical solution: the cement density detection equipment with the temperature regulation structure comprises a test box 1, wherein the front end of the test box 1 is movably connected with a door plate 2, the outer wall of the door plate 2 is embedded with a transparent plate 3, a detection device 4 is arranged in the test box 1, the top end of the test box 1 is embedded with an adjustment mechanism 5, and a heat insulation plate 6 is embedded between two adjacent groups of test boxes 1; the adjustment mechanism 5 includes electromagnetic heater main part 501, electromagnetic heater main part 501 passes through the bolt demountable installation on the top of test box 1, electromagnetic heater main part 501 top inlays and is equipped with filter screen 502, electromagnetic heater main part 501 penetrates the inside one end of test box 1 and is fixed with heated board 503, heated board 503 bottom is located the both sides of detection device 4 and installs heat transfer plate 504, heated board 503 and heat transfer plate 504 mutually perpendicular, heated board 503 and heat transfer plate 504 constitute U font structure, detection device 4 has all been placed to the multiunit test box 1, simultaneously the top inlays electromagnetic heater main part 501 respectively, through adjusting electromagnetic heater main part 501 temperature, thereby heat heated board 503, and improve the contact surface of heat and air through heat transfer plate 504, quick adjustment test box 1 inside temperature, be convenient for carry out the detection of different temperatures to multiunit different test blocks simultaneously, thereby be used for data comparison, filter screen 502 inlays and is outside the electromagnetic heater main part 501 radiating end, avoid outside dust impurity to get into and adsorb and influence the heat dissipation.

Example two

The scheme in the first embodiment is further described below in conjunction with a specific working manner, and the details are described below:

As shown in fig. 2, fig. 3 and fig. 4, as the preferred embodiment, further, on the basis of the above-mentioned mode, the inner wall below of test box 1 is fixed with and holds in the palm carrier plate 7, slide groove 8 has been seted up to the central point of holding in the palm carrier plate 7, slide groove 8 has been seted up to the inside of slide groove 8, hold in the palm carrier plate 9 includes slide plate 901, slide plate 901 passes through slide groove 8 sliding connection in the top of holding in the palm carrier plate 7, reserve groove 906 has been seted up on the both sides that hold in the palm carrier plate 7 top was located slide groove 8, be provided with connecting plate 904 between slide plate 901 and the support carrier plate 7, connecting plate 904 is towards holding in the palm carrier plate 7 and reserve groove 906 and is corresponding the position and inlay and be equipped with a plurality of gyro wheels 905, connecting plate 904 is towards the outer wall equidistance equispaced evenly installation multiunit damping spring 902 of slide plate 901, one side fixed mounting of connecting plate 904 top damping spring 902 has telescopic link 903, connecting plate 904 passes through damping spring 902 and slide plate 901 elastic connection, constitute sliding structure between slide plate 901 and the reserve groove 906 and the support carrier plate 7, slide plate 901 passes through gyro wheel 905 and slide groove 8 drives detection device 4 on holding in the top carrier plate 7, thereby be convenient for penetrating test box 1, the both sides of slide plate 901 and detect through slide groove 905 has the influence on the elasticity, and side damping plate 901 is avoided to have the elasticity to slide plate 901 to slide plate is inclined to be provided with the bearing plate, and the impact device.

As shown in fig. 4, as a preferred embodiment, further, a moving mechanism 10 is provided below the supporting plate 7, the moving mechanism 10 includes a connection plate 1001, the connection plate 1001 is fixedly installed on the bottom axial direction of the sliding plate 901 penetrating out of the supporting plate 7 through the chute 8, the bottom end of the connection plate 1001 is connected with a fixing plate 1002, an electric push rod 1003 is installed between the fixing plate 1002 and the inner wall of the test box 1, the fixing plate 1002 forms a sliding structure through the connection plate 1001 and the supporting plate 7, the fixing plate 1002 forms a telescopic structure through the electric push rod 1003 and the test box 1, and the fixing plate 1002 is pushed by the electric push rod 1003, so that the connection plate 1001 slides along the chute 8 on the supporting plate 7, the sliding plate 901 is conveniently driven by the electric push rod 1003 to slide, the supporting detection device 4 slides, the detection device 4 is prevented from being influenced by fluctuation during manual pushing, and meanwhile, the labor intensity is reduced.

From the above, it can be seen that:

The utility model aims at the technical problems that: in the prior art, the placing box is heated through the heating plate, but the temperature of the heating plate is inconvenient to accurately adjust in the use process, and when the cement density is detected, the corresponding temperature is adjusted according to the external temperature, and the detection is required to be carried out at different temperatures simultaneously so as to facilitate better data comparison, so that density detection equipment capable of adjusting the temperature is required; the technical scheme of each embodiment is adopted. Meanwhile, the implementation process of the technical scheme is as follows:

The detection device 4 is placed in the test box 1 by opening and closing the door plate 2, so that the internal condition is convenient to view through the transparent plate 3, and the electromagnetic heater main body 501 of the body adjusting mechanism 5 is embedded at the top end of the test box 1; the heating end is arranged in the test box 1, the radiating end is arranged on one side of the control end at the top end of the electromagnetic heater main body 501, the filter screen 502 is embedded to prevent dust from falling into the electromagnetic heater main body 501, the heating temperature is convenient to adjust, the heated plate 503 is heated, the temperature in the test box 1 is changed, meanwhile, the heat transfer plate 504 is matched to improve the contact surface with air to rapidly transfer heat, the temperature divergence is improved, four groups of test boxes 1 are arranged, the heat insulation plates 6 are arranged between the two groups to prevent the temperature from being influenced mutually, so that a plurality of groups of cement samples can be conveniently adjusted to different temperatures simultaneously for detection, and the accuracy of detection is improved by comparison data;

The detection device 4 is fixed on the sliding plate 901 of the supporting mechanism 9 through bolts, the sliding plate 901 passes through the sliding groove 8 formed in the supporting plate 7, so that the detection device 4 is conveniently driven to penetrate into the test box 1, meanwhile, a connecting plate 904 is arranged between the sliding plate 901 and the supporting plate 7, a damping spring 902 is arranged between the connecting plate 904 and the sliding plate 901, a roller 905 is embedded in the outer wall of the supporting plate 7 and penetrates into a reserved groove 906 formed in the supporting plate 7, so that the sliding smoothness of the sliding plate 901 is improved, the damping spring 902 has shock absorption, meanwhile, two groups of telescopic rods 903 are arranged on one side of the damping spring 902 between the bottom end of the sliding plate 901 and the supporting plate 7, the damping spring 902 is prevented from being elastically deviated or distorted in the sliding process, and the stability of the sliding plate 901 is preserved; the sliding plate 901 penetrates out of the connecting plate 1001 of the moving mechanism 10 axially fixed at the bottom end of the sliding groove 8, an electric push rod 1003 is arranged between the fixed plate 1002 connected with the bottom end of the connecting plate 1001 and the inner wall of the test box 1, and the fixed plate 1002 is pushed by the electric push rod 1003, so that the sliding plate 901 is driven to slide by the connecting plate 1001, and the pushing and carrying mechanism 9 drives the detecting device 4 to penetrate out of or into the test box 1, so that instability caused by manual pulling is avoided.

Through the arrangement, the application can solve the technical problems, and simultaneously realize the following technical effects:

According to the utility model, the sliding plate 901 drives the detection device 4 to slide on the support carrier plate 7 through the chute 8, so that the detection device is conveniently penetrated into the test box 1, the sliding plate 901 elastically pushes the connecting plate 904 through the damping spring 902, so that the roller 905 at the bottom end of the connecting plate 904 penetrates into the reserved groove 906 formed in the support carrier plate 7, the sliding smoothness of the sliding plate 901 is improved, meanwhile, the connecting plate 904 has a certain damping property, and the sliding plate 904 is supported by the telescopic rod 903, so that the sliding plate 901 is prevented from being deviated due to deviation in sliding, and the detection of the detection device 4 is influenced;

According to the utility model, the fixed plate 1002 is pushed by the electric push rod 1003, so that the connecting plate 1001 carries the sliding plate 901 to slide along the chute 8 on the carrying plate 7, the sliding plate 901 is conveniently driven by the expansion and contraction of the electric push rod 1003, the carrying detection device 4 slides, the influence on the detection device 4 caused by fluctuation generated during manual pushing is avoided, and meanwhile, the labor intensity is also reduced.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The cement density detection equipment with the temperature regulation structure is characterized by comprising a test box (1), wherein the front end of the test box (1) is movably connected with a door plate (2), the outer wall of the door plate (2) is embedded with a transparent plate (3), a detection device (4) is arranged in the test box (1), the top end of the test box (1) is embedded with an adjustment mechanism (5), and a heat insulation plate (6) is embedded between two adjacent groups of test boxes (1);

the electromagnetic heater comprises a test box (1), and is characterized in that the adjusting mechanism (5) comprises an electromagnetic heater main body (501), the electromagnetic heater main body (501) is detachably mounted at the top end of the test box (1) through bolts, a filter screen (502) is embedded at the top end of the electromagnetic heater main body (501), a heated plate (503) is fixed at one end of the electromagnetic heater main body (501) penetrating into the test box (1), and heat transfer plates (504) are mounted at two sides of the bottom end of the heated plate (503) located at the detection device (4).

2. A cement density detecting apparatus provided with a temperature adjusting structure according to claim 1, wherein the heat receiving plate (503) and the heat transfer plate (504) are perpendicular to each other, and the heat receiving plate (503) and the heat transfer plate (504) constitute a U-shaped structure.

3. The cement density detection device with the temperature regulation structure according to claim 1, wherein a supporting plate (7) is fixed below the inner wall of the test box (1), a sliding groove (8) is formed in the center position of the supporting plate (7), and a supporting mechanism (9) penetrates through the sliding groove (8).

4. The cement density detection device with the temperature regulation structure according to claim 3, wherein the supporting mechanism (9) comprises a sliding plate (901), the sliding plate (901) is slidably connected to the upper portion of the supporting plate (7) through a sliding groove (8), reserved grooves (906) are formed in two sides of the sliding groove (8) at the top end of the supporting plate (7), a connecting plate (904) is arranged between the sliding plate (901) and the supporting plate (7), a plurality of rollers (905) are embedded in positions, corresponding to the reserved grooves (906), of the connecting plate (904) facing the supporting plate (7), a plurality of groups of damping springs (902) are uniformly installed on the outer wall surface of the sliding plate (901) at equal intervals, and telescopic rods (903) are fixedly installed on one side of the damping springs (902) at the top end of the connecting plate (904).

5. The cement density detection apparatus provided with the temperature adjustment structure according to claim 4, wherein the connecting plate (904) is elastically connected with the sliding plate (901) through a damping spring (902), and the connecting plate (904) and the carrier plate (7) form a sliding structure through a roller (905) and a reserved groove (906).

6. A cement density detection apparatus provided with a temperature regulation structure according to claim 3, characterized in that a moving mechanism (10) is provided below the supporting plate (7), the moving mechanism (10) comprises a joint plate (1001), the joint plate (1001) is fixedly installed on the bottom axial direction of the sliding plate (901) penetrating out of the supporting plate (7) through the sliding groove (8), the bottom end of the joint plate (1001) is connected with a fixing plate (1002), and an electric push rod (1003) is installed between the fixing plate (1002) and the inner wall of the test box (1).

7. The cement density detection apparatus provided with the temperature adjustment structure according to claim 6, wherein the fixing plate (1002) forms a sliding structure between the joint plate (1001) and the carrier plate (7), and the fixing plate (1002) forms a telescopic structure between the electric push rod (1003) and the test box (1).