CN217638528U - Cement density detection equipment - Google Patents

Abstract

The utility model relates to the technical field of detection equipment, in particular to cement density detection equipment, which comprises a base, a pillar, a shell, a cover plate and a feeding component; the feeding subassembly includes the lift post, the slider, the movable plate, electric putter, first link, the mount, funnel and quantitative component, lift post and base fixed connection, slider and lift post sliding connection, movable plate and slider fixed connection, electric putter's both ends respectively with base and movable plate fixed connection, first link and movable plate fixed connection, mount and first link fixed connection, the funnel sets up on the mount, the quantitative component sets up on the movable plate, thereby remove through the funnel and extend into the feeding that realizes the bottle in the detection bottle, thereby avoid adding the in-process of raw materials to spatter outside detecting the bottle, and then reduce data detection's accuracy.

Description

Cement density detection equipment

Technical Field

The utility model relates to a check out test set technical field especially relates to a cement density check out test set.

Background

The cement density refers to the mass of the cement in unit volume under a dry condition, the traditional detection method calculates the density of the cement by using the mass and the volume, but the required conditions are harsh and relatively troublesome, and meanwhile, the obtained data are inaccurate.

The existing detection method is a Lee method, and cement density is calculated by adding cement and anhydrous kerosene into a Lee bottle body to calculate the volume of discharged liquid, so that accurate cement density is obtained.

However, in the process of adding the raw materials, because the Li's bottle mouth is narrow, some raw materials are easy to spill out of the bottle body in the process of pouring the raw materials into the bottle body, and therefore the accuracy of obtaining data is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cement density detection equipment, at the in-process that adds the raw materials, because the li shi bottleneck is comparatively narrow and small, pours into the in-process of bottle and makes some raw materialss spill outside the bottle easily to reduced the accuracy of obtaining data.

In order to achieve the purpose, the utility model provides a cement density detection device, which comprises a base, a pillar, a shell and a cover plate,

also comprises a feeding component;

the feeding assembly comprises a lifting column, a sliding block, a moving plate, an electric push rod, a first connecting frame, a fixing frame, a funnel and a quantitative component, wherein the lifting column is fixedly connected with the base and is located at one side of the shell, the sliding block is slidably connected with the lifting column and is located at one side of the lifting column, the moving plate is fixedly connected with the sliding block and is located at one side of the sliding block, two ends of the electric push rod are respectively fixedly connected with the base and the moving plate, the electric push rod is located between the base and the moving plate, the first connecting frame is fixedly connected with the moving plate and is located at one side of the moving plate, the fixing frame is fixedly connected with the first connecting frame and is located at one side of the first connecting frame, the funnel is arranged on the fixing frame and is located at one side of the fixing frame, and the quantitative component is arranged on the moving plate.

The quantitative component comprises a connecting rod, a second connecting frame, a connecting plate and a measuring cylinder, and the connecting rod is fixedly connected with the moving plate and is positioned on one side of the moving plate, which is far away from the electric push rod; the second connecting frame is fixedly connected with the connecting rod and is positioned on one side of the connecting rod; the connecting plate is fixedly connected with the second connecting frame and is positioned on one side of the second connecting frame; the measuring cylinder is fixedly connected with the connecting plate and is positioned on one side of the connecting plate.

The quantitative component further comprises a guide pipe, and the guide pipe is communicated with the measuring cylinder and is positioned on one side of the measuring cylinder.

Wherein, the feeding subassembly still includes the observation window, the observation window with shell fixed connection, and be located one side of shell.

The feeding assembly further comprises a heating plate, and the heating plate is fixedly connected with the shell and located on one side of the shell.

The cement density detection equipment further comprises a rotating assembly, and the rotating assembly is arranged on the base.

The rotating assembly comprises a rotating motor, a rotating shaft, a rotating table and a locking frame, wherein the rotating motor is fixedly connected with the base and is positioned on one side of the base; the rotating shaft is connected with the output end of the rotating motor and is positioned on one side of the rotating motor close to the shell; the rotating table is fixedly connected with the rotating shaft, is rotatably connected with the shell and is positioned on one side of the rotating shaft close to the shell; the locking frame is fixedly connected with the rotating table and is positioned on one side of the rotating table.

The utility model discloses a cement density check out test set is through putting into the detection bottle in the shell, through thereby electric putter's drive drives the movable plate is in carry out the lift removal in the lift post, through thereby the removal of movable plate drives the removal of first link, through thereby the removal area point of first link the removal of mount, through thereby the removal drive of mount the block hangs funnel on the mount carries out the lift removal, makes the one end of funnel stretches into in the detection bottle from the bottleneck of detecting the bottle to extend to the position that is close to the bottom of the bottle, through two behind respectively quantitative addition anhydrous kerosene and cement in the graduated flask, through the stand pipe flow falls on the funnel, through thereby the funnel removes and extends to realize the feeding to the bottle in the extension bottle to thereby avoid adding the in-process of raw materials and fall outside the detection bottle, and then reduce the accuracy that data detected.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic structural diagram of a cement density detection apparatus according to a first embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a feeding assembly according to a first embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a cement density detection apparatus according to a second embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a rotating assembly according to a second embodiment of the present invention.

In the figure: 101-base, 102-support column, 103-shell, 104-cover plate, 105-feeding component, 106-lifting column, 107-slide block, 108-moving plate, 109-electric push rod, 110-first connecting frame, 111-fixing frame, 112-funnel, 113-observation window, 114-heating plate, 115-connecting rod, 116-second connecting frame, 117-connecting plate, 118-measuring cylinder, 119-guide tube, 201-rotating component, 202-rotating motor, 203-rotating shaft, 204-rotating table and 205-locking frame.

Detailed Description

The embodiments of the invention will be described in detail hereinafter, examples of which are illustrated in the accompanying drawings, and the embodiments described hereinafter with reference to the drawings are exemplary and intended to be illustrative of the invention and should not be construed as limiting the invention.

The first embodiment of the present application is:

referring to fig. 1 and fig. 2, wherein fig. 1 is a schematic structural diagram of a cement density detection device according to a first embodiment of the present invention, and fig. 2 is a schematic structural diagram of a feeding assembly according to the first embodiment of the present invention. The utility model provides a cement density detection equipment, including base 101, pillar 102, shell 103, apron 104 and feeding subassembly 105, feeding subassembly 105 includes lift post 106, slider 107, movable plate 108, electric putter 109, first link 110, mount 111, funnel 112, ration component, observation window 113 and hot plate 114, the ration component includes connecting rod 115, second link 116, connecting plate 117, graduated flask 118 and stand pipe 119.

For the present embodiment, there are four support columns 102, four support columns 102 are fixedly mounted on the base 101 by bolts, the support columns 102 are supported by the base 101, the housing 103 is welded to the four support columns 102, the housing 103 is supported by the support columns 102, the cover plate 104 is fixedly mounted on the housing 103 by bolts, the bottle body is put into the housing 103 by removing the cover plate 104, and the temperature in the housing 103 can be controlled by the housing 103, so that the bottle body in the housing 103 can detect the cement density data.

Wherein, the lifting column 106 is fixedly connected with the base 101 and is located at one side of the base 101 close to the housing 103, the slider 107 is slidably connected with the lifting column 106 and is located at one side of the lifting column 106, the moving plate 108 is fixedly connected with the slider 107 and is located at one side of the slider 107, two ends of the electric push rod 109 are respectively fixedly connected with the base 101 and the moving plate 108, the electric push rod 109 is located between the base 101 and the moving plate 108, the first connecting frame 110 is fixedly connected with the moving plate 108 and is located at one side of the moving plate 108, the fixing frame 111 is fixedly connected with the first connecting frame 110 and is located at one side of the first connecting frame 110, the funnel 112 is arranged on the fixing frame 111 and is located at one side of the fixing frame 111, and the quantitative component is arranged on the moving plate 108, the lifting column 106 is welded on the base 101, the lifting column 106 is supported by the base 101, there are two sliders 107, the two sliders 107 are slidably connected in the grooves of the lifting column 106, the moving plate 108 is welded on the two sliders 107, the moving plate 108 can be made to directionally slide in the lifting column 106 by the directional sliding of the sliders 107 in the lifting column 106, the electric push rod 109 is fixedly installed on the base 101 by bolts, the electric push rod 109 is supported by the base 101, the electric push rod 109 is fixedly installed below the moving plate 108 by bolts, a corresponding power source is provided for the movement of the moving plate 108 by the driving of the electric push rod 109, so that the moving plate 108 can be made to move up and down in the lifting column 106, the first connecting frame 110 is welded on the moving plate 108, one end of the first connecting frame 110 extends out of the lifting column 106, the first connecting frame 110 can be driven to move by the movement of the moving plate 108, the fixing frame 111 is welded on the first connecting frame 110, the fixing frame 111 is driven to move up and down by the movement of the first connecting frame 110, the funnel 112 is clamped and hung on the fixing frame 111, the funnel 112 is driven to move by the movement of the fixing frame 111, one end of the funnel 112 extends into the detection bottle body under the movement of the fixing frame 111, the quantitative component is arranged on the moving plate 108, and raw materials of the detection bottle body through the funnel 112 can be quantified by the quantitative component.

Secondly, the connecting rod 115 is fixedly connected with the moving plate 108 and is positioned on one side of the moving plate 108 far away from the electric push rod 109; the second connecting frame 116 is fixedly connected with the connecting rod 115 and is positioned at one side of the connecting rod 115; the connecting plate 117 is fixedly connected with the second connecting frame 116 and is located at one side of the second connecting frame 116; the measuring cylinder 118 is fixedly connected with the connecting plate 117 and located on one side of the connecting plate 117, the connecting rod 115 is welded above the moving plate 108, the moving plate 108 moves to drive the connecting rod 115 to move, the second connecting frame 116 is welded on the connecting rod 115, one end of the second connecting frame 116 extends out of the lifting column 106, the connecting rod 115 moves to drive the second connecting frame 116 to move, the connecting plate is welded on one end of the second connecting frame 116, the second connecting frame 116 moves to drive the connecting plate 117 to move, the two measuring cylinders 118 are bonded on the connecting plate 117, the measuring cylinder 118 moves by the movement of the connecting plate 117, scales are arranged on the measuring cylinder 118, the two guide pipes 119 are arranged, the two guide pipes 119 are communicated below the two corresponding measuring cylinders 118, and the raw materials entering the detection bottle body can be quantitatively added through the measuring cylinders 118 and then fall into the funnel 112 through the guide pipes 119 below the measuring cylinders 118.

Meanwhile, the observation window 113 is fixedly connected with the housing 103 and is located on one side of the housing 103, the observation window 113 is adhered to the housing 103, the observation window 113 is made of glass, and the detection condition in the housing 103 can be clearly connected through the observation window 113.

In addition, the heating plate 114 is fixedly connected to the housing 103 and located at one side of the housing 103, the heating plate 114 is fixedly mounted on the housing 103 by bolts, and the detection environment in the housing 103 can be heated by the heating plate 114, so that the accuracy of the detection data can be ensured by maintaining an accurate heating environment.

When the cement density detection device is used, a detection bottle body is placed in the shell 103, the movable plate 108 is driven to move up and down in the lifting column 106 by the driving of the electric push rod 109, the first connecting frame 110 is driven to move by the movement of the movable plate 108, the fixing frame 111 is moved by the movement of the first connecting frame 110, the funnel 112 clamped and hung on the fixing frame 111 is driven to move up and down by the movement of the fixing frame 111, one end of the funnel 112 extends into the detection bottle body from the bottle opening of the detection bottle body and extends to a position close to the bottom of the bottle body, after anhydrous kerosene and cement are quantitatively added in the two measuring cylinders 118 respectively, the anhydrous kerosene and cement flow down onto the funnel 112 through the guide pipe 119, and the feeding of the bottle body is realized through the funnel 112, so that the funnel is prevented from splashing outside the detection bottle body in the process of adding raw materials, and the accuracy of data detection is further reduced.

The second embodiment of the present application is:

on the basis of the first embodiment, please refer to fig. 3 and fig. 4, fig. 3 is a schematic structural diagram of a cement density detection apparatus according to a second embodiment, and fig. 4 is a schematic structural diagram of a rotating assembly according to a second embodiment of the present invention. The utility model provides a cement density check out test set still includes runner assembly 201, runner assembly 201 is including rotating motor 202, axis of rotation 203, swivel mount 204 and locking frame 205.

To this embodiment, rotating assembly 201 sets up on the base 101, through rotating assembly 201 can carry out the automatic mixing through machinery to the data that obtains the detection after the raw materials acceleration mixing in the improvement detection bottle, and then improved the efficiency that detects.

The rotating motor 202 is fixedly connected with the base 101 and is located on one side of the base 101; the rotating shaft 203 is connected with the output end of the rotating motor 202 and is positioned on one side of the rotating motor 202 close to the shell 103; the rotating table 204 is fixedly connected with the rotating shaft 203, is rotatably connected with the housing 103, and is located on one side of the rotating shaft 203 close to the housing 103; locking frame 205 with revolving stage 204 fixed connection, and be located one side of revolving stage 204, it installs to rotate motor 202 bolt fixed mounting on the base 101, through the base 101 is realized right the support of rotating motor 202, axis of rotation 203 is connected the output of rotating motor 202, thereby through the drive that rotates motor 202 drives axis of rotation 203 rotates, it installs to rotate 204 bolt fixed mounting in axis of rotation 203, and with the shell 103 rotates to be connected, thereby through the rotation of axis of rotation 203 drives the revolving stage 204 is in rotate in the shell 103, locking frame 205 block is in on the revolving stage 204, through locking frame 205 can be right detection bottle on the revolving stage 204 carries out fixed spacing, thereby avoids the bottle is in the emergence when rotating on the revolving stage 204 and mixing is rocked.

When the cement density detection equipment is used, a detection bottle body is placed on the rotating table 204 to add raw materials, and then the detection bottle body is fixed on the rotating table 204 through the locking frame 205, so that the rotation of the rotating table 204 is driven by the rotating motor 202 to drive the detection bottle body on the rotating table 204 to rotate, the raw materials in the detection bottle body are mixed in an acceleration mode, detected data are obtained quickly, and the detection efficiency is improved.

While the above disclosure describes one or more preferred embodiments of the present invention, it should be understood that there is no intent to limit the scope of the claims, and it is intended that all or a portion of the process flow of the above embodiments be practiced and equivalents thereof within the scope of the claims.

Claims (7)

1. A cement density detection device comprises a base, a pillar, a shell and a cover plate, and is characterized in that,

also comprises a feeding component;

the feeding assembly comprises a lifting column, a sliding block, a moving plate, an electric push rod, a first connecting frame, a fixing frame, a funnel and a quantitative component, wherein the lifting column is fixedly connected with the base and is located on one side, close to the shell, of the base, the sliding block is slidably connected with the lifting column and is located on one side of the lifting column, the moving plate is fixedly connected with the sliding block and is located on one side of the sliding block, two ends of the electric push rod are respectively fixedly connected with the base and the moving plate, the electric push rod is located between the base and the moving plate, the first connecting frame is fixedly connected with the moving plate and is located on one side of the moving plate, the fixing frame is fixedly connected with the first connecting frame and is located on one side of the first connecting frame, the funnel is arranged on the fixing frame and is located on one side of the fixing frame, and the quantitative component is arranged on the moving plate.

2. The cement density detection apparatus according to claim 1,

the quantitative component comprises a connecting rod, a second connecting frame, a connecting plate and a measuring cylinder, and the connecting rod is fixedly connected with the movable plate and is positioned on one side of the movable plate, which is far away from the electric push rod; the second connecting frame is fixedly connected with the connecting rod and is positioned on one side of the connecting rod; the connecting plate is fixedly connected with the second connecting frame and is positioned on one side of the second connecting frame; the measuring cylinder is fixedly connected with the connecting plate and is positioned on one side of the connecting plate.

3. The cement density detection apparatus according to claim 2,

the quantitative component further comprises a guide pipe, and the guide pipe is communicated with the measuring cylinder and is positioned on one side of the measuring cylinder.

4. The cement density detection apparatus according to claim 1,

the feeding assembly further comprises an observation window, and the observation window is fixedly connected with the shell and is positioned on one side of the shell.

5. The cement density detection apparatus according to claim 1,

the feeding assembly further comprises a heating plate, and the heating plate is fixedly connected with the shell and is positioned on one side of the shell.

6. The cement density detection apparatus according to claim 1,

the cement density detection equipment further comprises a rotating assembly, and the rotating assembly is arranged on the base.

7. Cement density detection apparatus according to claim 6,

the rotating assembly comprises a rotating motor, a rotating shaft, a rotating table and a locking frame, and the rotating motor is fixedly connected with the base and is positioned on one side of the base; the rotating shaft is connected with the output end of the rotating motor and is positioned on one side of the rotating motor close to the shell; the rotating platform is fixedly connected with the rotating shaft, is rotatably connected with the shell and is positioned on one side of the rotating shaft close to the shell; the locking frame is fixedly connected with the rotating platform and is positioned on one side of the rotating platform.

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