JP3242671U - Limestone slurry processing equipment used for filtration mechanism and density measurement for thermal power plants - Google Patents

Abstract

A filtration mechanism and a limestone slurry treatment apparatus are provided that can reduce construction costs, reduce industrial environmental pollution caused by discharge of limestone slurry wastewater, and improve economic efficiency. A limestone slurry processing apparatus for filtration mechanism and density measurement of a thermal power plant includes an adapter unit 100, a wiper unit 200, the adapter unit including a housing 101, a gripping knob 102, an engaging tool, the gripping knobs respectively The housing is drilled on both sides, the engaging tool is installed on the inner wall of the housing, the gripping knob is connected with the screw of the housing, the engaging tool is rotationally fitted with the gripping knob, and the wiper unit includes a filter, a squeegee, a pusher, A first partition plate is installed inside the housing, a squeegee is installed at the upper end of the filter, a pusher is installed at the upper end of the filter, the pusher is installed through the squeegee, and the first partition plate is at the rear side of the housing. Install on the wall. [Selection drawing] Fig. 1

Description

This utility model relates to the field of lime water treatment, specifically to a filtration mechanism and a limestone slurry treatment apparatus used for density measurement for thermal power plants.

With the rapid development of China's economy, a large amount of limestone slurry wastewater is generated every year during the operation of China's thermal power plants, the absolute majority of which is directly transported to the suburbs without treatment or deposited there. They can be easily buried, and according to relevant studies, these limestone slurry wastewaters can be stored in their own p
Due to its high H value, direct discharge into the water body without treatment will affect the metabolism of aquatic organisms,
It has a direct toxic effect on aquatic organisms, resulting in digestive system upset, and because these limestone slurry wastewaters contain a lot of lime, the accumulation of lime will affect the photocooperation of plants. , destroying the living space of benthic animals and filtering the limestone slurry wastewater used in existing thermal power plants, the mechanism is relatively complicated, the construction cost is high, and the maintenance is difficult at the same time.
Users often damage the limestone slurry wastewater filtration mechanism during use, and the phenomenon of spending energy on repairing causes great inconvenience to the operation of thermal power plants and wastes unnecessary repair costs.
Conventional thermal power plants often adopt only a filtration mechanism, and the limestone slurry is discharged directly after being filtered. This can bring the economic effect of recovering solid limestone to thermal power plants, and is not conducive to environmental improvement. The treatment equipment adopted by some thermal power plants is costly and treats the slurry wastewater, but the purchase, use and maintenance of the treatment equipment in thermal power plants require a large amount of financial resources. Thermal power plants cannot bring economic benefits.

The purpose of this section is to review some aspects of the embodiments of the present utility model and to briefly introduce some preferred embodiments. This section and the abstract of the specification and the title of the utility model of this application may be simplified or omitted so as not to obscure the purpose of this section, the abstract of the specification and the title of the utility model; cannot be used to limit the scope of this utility model.
In view of the high construction cost and inconvenient maintenance of the conventional thermal power plant limestone slurry wastewater filtration system, this utility model is proposed.
In order to solve the above technical problems, this utility model provides the following technical solution: the filtering mechanism includes a housing, a gripping knob and a locking device, and the gripping knobs are respectively drilled on both sides of the housing. , the locking device is installed on the inner wall of the housing, the gripping knob is threadedly coupled with the housing, the locking device is rotationally coupled with the gripping knob, and a brush unit;
The filter is installed inside the housing, the squeegee is installed on the upper end of the filter, the pusher is installed on the upper end of the filter, and the pusher is installed on the upper end of the filter. A squeegee is installed through, the first partition plate is installed on the rear wall surface of the housing, the filter is slidably fitted in the housing, the squeegee is screwed to the presser, and the first partition plate is It slides into the housing.
As a preferred aspect of the filtering mechanism of the present utility model, the chuck knob includes a knob bored in the outer wall of the housing, a first spring, a slide block, and an engagement block, and the knob is attached to the outer wall of the housing. The first spring is installed on the inner wall of the housing, the slide block is drilled on the outer wall of the housing, the engagement block is installed on an inner end of the knob, and the knob is on the housing the knob is rotationally fitted in the engagement block; the slide block is fixedly connected to the engagement block; the first spring is movably fitted in the housing; It was moved and fitted to the engagement block.
As a preferred embodiment of the filtering mechanism of the present utility model, the gripping knob member further comprises: the slide being opened in the slide; the slide being installed at one end inside the slide; slides, including slides.
As a preferred aspect of the present utility model registration filtering mechanism, the locking tool includes a moving groove and a moving block, the moving groove is formed on an inner wall surface of the locking block, and the moving block is configured to move the moving block. Installed inside a groove, the moving block is slidably fitted into the moving groove.
As a preferred embodiment of the filtering mechanism of the present utility model, the filtering material includes a handle and a filtering mesh, the filtering mesh is installed inside the casing, the handle is installed at the front end of the filtering mesh, and the handle is located at the front end of the filtering mesh. fixedly connected to a filtering net, said filtering net being fixedly connected to said moving block;
As a preferred embodiment of the filtering mechanism of the present utility model, the pusher includes a pedestal, a wire rod, and a slide rod, the pedestal is installed on the side inner wall of the housing, and is installed between the pedestals , the pedestals are installed between the pedestals, the pedestals are connected to the threads of the blades, the slide bar is fitted to the blades, and the pedestals are fixedly connected to the housing.
Beneficial effect of this filtration mechanism: Through the filtration mechanism, the solid limestone in the limestone slurry wastewater is filtered and concentrated, and then the solid limestone is collected through the blades, reducing the solid content of the limewater wastewater and reducing environmental pollution. Together, the plant can intensively reuse limestone solids, bringing economic efficiency to thermal power plants.
In view of the problem that the conventional limestone slurry wastewater from thermal power plants is not treated and discharged directly, causing environmental pollution, the present utility model is proposed.
In order to solve the above technical problems, this utility model provides the following technical solutions: Limestone slurry processing equipment for thermal power plant density measurement, including valve unit, translating member, supporting column, oscillating member, valve. a housing, wherein the translating member is installed on the side of the valve housing; the support column is installed on the side of the valve housing; the swinging member is installed on the side of the valve housing; fixedly connected to a housing, said support post fixedly connected to said valve housing, said rocker member being rotationally fitted to said support post, comprising a water valve housing, a closure member, a second separator, said closure member being connected to said valve housing; The second separator is installed on the front side wall of the housing, the closing member is rotationally fitted to the water valve housing, and the second separator is slidingly fitted to the housing. match.
As a preferred embodiment of the limestone slurry processing apparatus used for density measurement for thermal power plants of the present utility model, the translation body includes a translation auxiliary block, a first movable door and a second movable door, and the translation auxiliary block is the gas valve housing. installed on the side, wherein the first moving door is installed on the bottom end of the translation auxiliary block, and the second moving door is installed on the side of the first moving door, the translation auxiliary block is fixedly connected to the valve housing; The first moving door was slidably fitted to the translation assisting block, and the second moving door was slidably fitted to the translational assisting block.
As a preferred embodiment of the limestone slurry processing apparatus used for the thermal power plant density measurement of the present utility model, the rocking member comprises a first rocking block, a second rocking block, a third rocking block, a fourth rocking block, and a rocking block. The cavity includes the first rocking block, the second rocking block, the third rocking block, the fourth The first swing block is installed on the side of the air valve housing, the second swing block is installed on the side of the air valve housing, and the third swing block is installed on the side of the air valve housing. said fourth swaying block is installed on the side of said air valve housing, said slide posts are respectively installed inside said cavity, said first engagement block is located at the lower end of said second swaying block wherein the second engaging block is installed at the lower end of the third swinging block, the first swinging block is pivotally fitted to the supporting column, and the second swinging block is connected to the supporting column , the third swing block is pivotally fitted to the support column, the fourth swing block is pivotally fitted to the support column, and two of the sliding columns are the The first moving door is fixedly connected, the remaining sliding post is fixedly connected to the second moving door, and the first interlocking block is connected to the second moving door.
Fixedly connected to the rocker block, the second engagement block is fixedly connected to the third rocker block.
As a preferred embodiment of the limestone slurry processing apparatus used for density measurement for thermal power plants of the present utility model, the closing member includes a push handle, a push door, a push groove and a pipe block, and the push door is inside the water valve casing. installing, the push groove is opened on the water valve casing, and the pipe block is installed on the inner wall of the water valve casing;
The push handle passes through the push groove and is installed on the push groove, the push handle is fixedly connected to the pipe block, and the push door is fixedly connected to the pipe block. Beneficial effect of the limestone slurry treatment equipment for density measurement of this thermal power plant: Through the waste lime water treatment equipment, carbon dioxide aeration method is used to generate calcium oxide and water by chemical reaction of waste lime water with carbon dioxide chemical reaction, and calcium oxide is precipitated. The factory can collect and sell the calcium oxide as well as use it to discharge water and reduce the environmental pollution caused by the discharge, thus enhancing its own economic efficiency.

In order to describe the technical aspects of the embodiments of the present invention more clearly, the following briefly describes the drawings that need to be used in the description of the embodiments. Apparently, the drawings in the following description are just some embodiments of the present invention, and without creative labor, those skilled in the art will
Other drawings can be derived from these drawings.
Structural perspective view of the main body of this utility model Another angle perspective structural view of the present utility model Left side view of this utility model Schematic diagram of partial enlarged structure in A of FIG. Right side view of this utility model Cross-sectional plan view of the utility model Left sectional view of this utility model Schematic view of partially enlarged structure in FIG. 7B Right side view of this utility model Perspective structural drawing of the water valve unit of this utility model It is a cross-sectional view of the utility model type water valve unit.

In order to make the above objects, features, and advantages of the present utility model more clear and comprehensible, the specific embodiments of the present utility model are described in detail below together with the specification and drawings.
Although the following description sets forth many specific details for a thorough understanding of this utility model,
The utility model can also be implemented using other methods that can be analogized without violating the connotations of the utility model, and therefore the utility model is limited to the specific embodiments disclosed below. not.
Second, as used herein, "one embodiment" or "embodiment" refers to a particular feature, structure, or characteristic that can be included in at least one embodiment of the utility model. The appearances of "in one embodiment" in different places in this specification are not all referring to the same embodiment, nor are they referring to embodiments that are solely or selectively exclusive of other embodiments.

Example 1
1, 2, 5, 6, 7 and 8, which is a first embodiment of the present utility model, this embodiment has a filtering mechanism comprising an engaging unit 100 and a scraping unit 200. , the user engages the filtering mechanism with the housing 101 through the engaging unit 100, thereby achieving the purpose of filtering the solid limestone in the limestone slurry wastewater, while the scraping unit 200
The limestone solids filtered through are scraped from the filtration mechanism and collected for reuse.
Specifically, a housing 101, grip knobs 102 drilled on both sides of the housing 101, grip knobs 103 provided on the inner wall of the housing 101, and housing 1
01, and the gripping knob 10 rotationally fitted to the gripping knob 102.
3 and a gripping knob 10 in which two gripping knobs 103 are pivoted and a gripping knob 102 is pivotally fitted.
2, the housing 101 and the filter 201 are tightly fitted together to prevent rattling and falling off.
Furthermore, the wiper unit 200 includes a filter 201, a wiper 202, a pusher 203, and a first partition plate 204. The filter 201 is installed inside the housing 101, and the wiper 2
02 is installed at the upper end of the filter 201, the pusher 203 is installed at the upper end of the filter 201, the pusher 203 is installed through the wiper 202, and the first partition plate 204 is installed at the housing 1
01, the filter 201 is slidably fitted into the housing 101, and the wiper 2
02 is screwed into the pusher 203, the first partition plate 204 is slidably fitted into the housing 101, the filter chamber 201 and the locking member 103 are closely attached by sandwiching the knob 102, and the first partition plate 2
04 is pushed into the housing 101, the first partition plate 204 and the housing 101 are made of rubber to prevent flooding, and after the limestone slurry wastewater is filtered, the pusher 203 is rotated to move the squeegee 202. The filtered solid limestone is filtered by the first partition plate 204
and open the first partition plate 204, so that the filtered solid limestone can be collected.
In use, the filter 201 is placed between the housings 101 and the knob 102 is rotated to
Collecting the engagement gap 103 inside to clamp the filter 201, the employee pours the limestone slurry wastewater into the equipment through the upper hole of the housing, the filter 201 filters the limestone slurry wastewater, filters the solid limestone, filters is completed, the pressing member 203 is rotated to move the squeegee 202 to the first partition plate 204, thereby collecting the solid limestone on the first partition plate 204, opening the first partition plate 204 to collect the solid limestone, Complete filtration of limestone slurry wastewater.

Example 2
1, 2, 5, 6, 7 and 8 are the second embodiment of the present utility model, which is based on the above embodiment.
Specifically, the gripping knob 102 includes a knob 102a, a first spring 102b, a slide block 102c, and an engaging block 102d. The slide block 102c is drilled through the outer wall of the housing 101, the engaging block 102d is installed at one inner end of the knob 102a, the knob 102a is screwed to the housing 101, and the knob 102a is engaged. Combined block 102d
The slide block 102c is fixedly connected to the engagement block 102d.
2d, and put the filter net 201b between the housings 101, the user rotates the knob 102a, the bottom end of the knob 102a is a bolt, and the bolts at both ends of the housing are the first springs 102b during rotation. is pressed against the wall surface of the housing 101, and at the same time, the slide block 102c is gathered inwardly and closely aligned with the moving block 103b at the bottom end of the filter net 201b to achieve the purpose of tightening the filter net 201b, so that the filter net 201b is in use. to prevent it from swinging or falling off.
Preferably, gripping the knob 102 comprises a chute 102e opened on the engagement block 102d, a slider 102f located on the inner end of the knob 102a, and a slider 102f.
02f and a slider 102f with which the chute 102e is rotationally fitted;
02a has a slider 102f fixedly mounted thereon, and a moving block 103
b opens the chute 102e, the slider 102f and the chute 102e are rotationally fitted, and the knob 102a may be screwed into the housing 101 during rotation;
3b can be screwed together.
Preferably, the locking device 103 includes a moving groove 103a, a moving block 103b, and the moving groove 10
3a is opened on the inner wall surface of the engaging block 102d, and the moving block 103b is formed in the moving groove 10
3a, the moving block 103b is slidably fitted into the moving groove 103a, the filter net 201b is fixedly attached to the moving block 103b, and the moving block 103b and the moving groove 103a slide the slide block 102c through the knob 102a. Move and gather inward to tightly engage the filter mesh 201b, making it convenient to pull out and use the filter mesh 201b.
Preferably, the filter 201 includes a handle 201a and a filter net 201b, the filter net 201b is installed inside the housing 101, the handle 201a is installed at the tip of the filter net 201b, the handle 201a is fixedly connected to the filter net 201b, and the filter is Net 201
b is fixedly connected with the moving block 103b, and the handle 201a and the pressing chamber 203 cooperate with each other, the filter net 201b can be lowered to a specific position after filtering the solid limestone, so that the employees can time convenient for organizing
Further, the pusher 203 is installed between a base 203a installed on the side inner wall of the housing 101, a screw 203b installed between the base 203a, a screw 203c installed between the base 203a, and the base 203a. a screw 203b screwed with the squeegee 202; a screw 203b screwed with the squeegee 202;
03c, the base 203a and the housing 101 are fixedly connected, and after the filter mesh 201b filters the solid limestone, the user's rotary handle 201a moves the squeegee 202 through the wire rod 203b between the rotary bases 203a, and the squeegee 202 is Most of the solid limestone is pressed against the first partition plate 204, and the squeegee 203c serves to prevent the squeegee 202 from being dislocated.
In use, the user places the moving block 103b at the bottom end of the filter screen 201b between the casings 101 corresponding to the moving grooves 103a, and then rotates the knob 102a so that the casing 10
The knobs 102a at both ends of 1 are gathered inside by moving the slide block 102c during rotation,
Further, while holding the filter net 201b, the first partition plate 204 is inserted into the casing 101, the limestone slurry waste water is put into the through hole above the casing, and after the filtration is completed, the filter net 201b is removed.
filters the solid limestone, the user rotates the handle 201a to rotate the wire rod 203b, the wire rod 203b moves the squeegee 202 in synchronization with the slide rod 203c, and transfers the solid limestone to the first partition plate 204. , then pull out the first partition plate 204,
The user collects the solid limestone from the first partition plate 204 and reuses it.

Example 3
1, 3, 4, 9, 10 and 11, the third embodiment of the present utility model, which is based on the above two embodiments, this embodiment provides a limestone slurry treatment apparatus used for density measurement for thermal power plants, a gas valve module 300 for the filtered limestone slurry wastewater to undergo a carbon dioxide aeration chemical reaction to produce calcium oxide and water;
After chemical reaction, the treated limestone slurry wastewater is discharged through the water valve unit 400 to reduce environmental pollution.
Specifically, the valve unit 300 includes a translation member 301 , a support column 302 , a swing member 303
, a valve housing 304 , the translation member 301 is installed on the side of the valve housing 304 , the support column 302 is installed on the side of the valve housing 304 , the swing member 303 is installed on the side of the valve housing 304 , the translation member 301 is fixedly connected to the valve housing 304, the support column 302 is fixedly connected to the valve housing 304, the rocking member 303 is pivotally connected to the support column 302, and the user can rock when the carbon dioxide aeration method needs to be performed. By swinging the moving member 303, the swinging member 303 moves the translating member 301 through the support member 302, thereby opening the valve unit 300, and the user can again exhaust the air through the fan, and the filtered Limestone slurry wastewater and carbon dioxide are brought into sufficient contact to cause a chemical reaction.
Preferably, the water valve unit 400 comprises a water valve housing 401, a closure member 402,
A second partition plate 403 is provided on the upper surface of the water valve housing 401 , the second partition plate 403 is installed on the front side wall of the housing 101 , and the closure member 402 is pivotally fitted into the water valve housing 401 . and the second partition plate 403 is slidably fitted to the housing 101,
When the chemical reaction by the carbon dioxide aeration method is completed, the user opens the water valve unit 400 by moving the closing member 402 on the water valve housing 401 to discharge the treated limestone slurry wastewater and produce the second separator 40
3 to be collected and used or used for sale.
Preferably, the translator 301 includes a translation assisting block 301a, a first moving door 301
b, including the second moving door 301c, the translation assist block 301a is the valve housing 304
, the first moving door 301b is installed at the lower end of the translation assisting block 301a, the second moving door 301c is installed at the side of the first moving door 301b, and the translation assisting block 3
01a is fixedly connected to the valve housing 304, the first moving door 301b slides into the translation assisting block 301a, the second moving door 301c slides into the translation assisting block 301a, and slides into the first moving door 301b. The second moving door 301c closes in the equipment idle state, and the translation assisting block 301a assists the mutual translational release of the first moving door 301b and the second moving door 301c when in use.
Preferably, the oscillator 303 includes a first rocking block 303a, a second rocking block 303b,
It includes a third swing block 303c, a fourth swing block 303d, a cavity 303e, a slide column 303f, a first engagement block 303g and a second engagement block 303h, wherein the cavity 303e comprises the first swing block 303a, the second The first swing block 30 is provided in the swing block 303b, the third swing block 303c, and the fourth swing block 303d, respectively.
3a is provided on the side surface of the valve housing 304, the second swing block 303b is provided on the side surface of the valve housing 304, and the third swing block 303c is provided on the side surface of the valve housing 304.
, the fourth swing block 303d is provided on the side of the valve housing 304, the slide columns 303f are respectively provided inside the cavity 303e, and the first swing block 303g is the bottom end of the second swing block 303b. provided in the second swing block 303
h is provided at the bottom end of the third swing block 303c, the first swing block 303a is pivotally engaged with the support column 302; 3
The swing block 303c is pivotally fitted to the support column 302, the fourth swing block 303d is pivotally fitted to the support column 302, two of which slide columns 303f are fixedly connected to the first movable door 301b, and the rest are The slide post 303f is fixedly connected to the second movable door 301c, the first engagement block 303g is fixedly connected to the second swing block 303b, and the second engagement block 303h is fixedly connected to the third swing block 303c. , when the user opens the valve unit 400, the first swing block 303a is swung. 303e and slide column 3
03f moves the second swing block 303b while sliding in cooperation with the second swing block 303b via a first engagement block 303g on the bottom and a second engagement block 303h on the bottom of the third swing block 303c. further move the third swing block 303c, and further move the fourth swing block 303d, thereby engaging the first moving door 301b and the second moving door 301b.
The moving doors 301c move parallel to each other to achieve the purpose of the on-off valve unit 300.
In addition, the closing member 402 includes a push handle 402a, a push door 402b, a push groove 402c and a pipe block 402d. , the pipe block 402d is installed on the inner wall of the water valve housing 401, the push handle 402a passes through the push groove 402c and is installed in the push groove 402c, the push handle 402a is fixedly connected to the pipe block 402d, and the push door 402b is connected to the pipe. Fixedly connected to the block 402d, when the chemical reaction of the carbon dioxide aeration method is completed, the user can move the pressing handle 402a over the pressing bath 402c, so that the pressing doors 402b are displaced from each other and out of close contact, and at the same time The piping block 402d can prevent the phenomenon of arbitrary infiltration of water from the pressing tank 402c when the limestone slurry wastewater is discharged.
When using, the user swings the first swing block 303a, the first swing block 303a can swing back and forth under the action of the support column 302, and at the same time the cavity between the first swing blocks 303a 303e and slide column 303f slide together to move the second swing block 303b, and the second swing block 303b moves the first engagement block 303g at the bottom.
and the second engagement block 303h at the bottom of the third swing block 303c,
By further moving the third swing block 303c and further moving the fourth swing block 303d on the same moving door, the first moving door 301b and the second moving door 301c can be mutually translated open, and the valve When the unit 400 is opened, the user can use the fan to exhaust the carbon dioxide inside the device, causing the chemical reaction of the carbon dioxide aeration method to produce calcium oxide and water, and when the chemical reaction is completed, The user pushes the push handle 402a into the push groove 4
02c so that the push doors 402b are out of alignment with each other and at the same time the pipe block 402d is pushed into the push grooves 402 in discharging the limestone slurry wastewater.
After the treated limestone slurry wastewater is discharged, the second partition plate 403 is sucked, and the user can remove calcium oxide from the second partition plate 403. was collected and used or sold to complete the entire process of filtering the limestone slurry wastewater.

It should be noted that although the above embodiments describe the invention in detail with reference to preferred embodiments without departing from the spirit and scope of the invention, those skilled in the art will appreciate that other modifications may be made without departing from the spirit and scope of the invention. ,
It should be understood that the technical scope of the present invention can be modified or equivalently replaced, and both should be included in the claims of the utility model.

Claims (10)

an adapter unit 100;
The adapter unit 100 is
a housing 101;
a gripping knob 102;
and a locking device 103,
The gripping knobs 102 are respectively drilled on both sides of the housing 101,
The locking tool 103 is provided on the inner wall of the housing 101,
The gripping knob 102 and the housing 101 are screwed together,
The locking tool 103 and the gripping knob 102 are rotationally engaged,
a wiper unit 200;
The wiper unit 200 is
a filter 201;
a squeegee 202;
a pressing member 203;
and a first partition plate 204,
The filter 201 is provided inside the housing 101,
The squeegee 202 is provided at the upper end of the filter 201,
The pressing member 203 is provided at the upper end of the filter 201,
The pressing member 203 is bored in the squeegee 202,
The first partition plate 204 is provided on the rear wall surface of the housing 101,
The filter 201 and the housing 101 are slidably fitted,
The squeegee 202 and the pressing member 203 are screwed together,
The first partition plate 204 is slidably fitted to the housing 101,
filtration mechanism. The filtration mechanism according to claim 1,
The grip knob 102 is
a knob 102a;
a first spring 102b;
a slide block 102c;
an engagement block 102d;
The knob 102a is bored in the outer wall of the housing 101,
The first spring 102b is provided on the inner wall of the housing 101,
The slide block 102c is bored in the outer wall of the housing 101,
The engagement block 102d is provided at one end inside the knob 102a,
The knob 102a and the casing 101 are coupled by screws,
The knob 102a and the engagement block 102d are rotationally fitted,
The slide block 102c and the engagement block 102d are fixedly connected,
the first spring 102b and the housing 101 are movably fitted,
said first spring 102b engages said engagement block 102d;
filtration mechanism. The filtration mechanism according to claim 2,
The gripping tab 102 further:
a chute 102e;
a slider 102f;
the chute 102e is opened in the engagement block 102d;
The slider 102f is provided at one end inside the knob 102a,
The slider 102f is rotationally fitted to the chute 102e,
filtration mechanism. The filtration mechanism according to claim 2,
The locking tool 103 is
a moving groove 103a;
a moving block 103b,
The moving groove 103a is formed on the inner wall surface of the engaging block 102d,
The moving block 103b is provided inside the moving groove 103a,
The moving block 103b is slidably fitted into the moving groove 103a,
filtration mechanism. The filtration mechanism according to claim 4,
The filter 201 is
a handle 201a;
a filter network 201b,
The filter net 201b is provided inside the housing 101,
The handle 201a is provided at the tip of the filter net 201b,
The handle 201a and the filter network 201b are fixedly connected,
The filter network 201b is fixedly connected to the moving block 103b,
filtration mechanism. A filtration mechanism according to claim 5,
The pusher 203 is
a base 203a;
a wire rod 203b;
a slide bar 203c,
The base 203a is provided on the side inner wall of the housing 101,
The wire rod 203b is provided between the bases 203a,
The slide bar 203c is provided between the bases 203a,
The wire rod 203b and the squeegee 202 are screwed together,
The slide bar 203c and the squeegee 202 are slidably fitted,
The base 203a is fixedly connected to the housing 101,
filtration mechanism. Limestone slurry processing equipment used for density measurement for thermal power plants,
including the filtration mechanism according to any one of claims 1 to 6, and
a valve unit 300;
The valve unit 300 is
a translator 301;
a support post 302;
an oscillator 303;
a valve housing 304;
The translator 301 is provided on the side of the valve housing 304,
The support column 302 is provided on the side of the valve housing 304,
The oscillator 303 is provided on the side surface of the valve housing 304,
The translator 301 and the valve housing 304 are fixedly connected,
The support column 302 and the valve housing 304 are fixedly connected,
The oscillator 303 and the support column 302 are rotationally fitted,
a water valve unit 400;
The water valve unit 400 is
a water valve housing 401;
a closure member 402;
and a second partition plate 403,
The closing member 402 is drilled on the upper surface of the water valve housing 401,
The second partition plate 403 is provided on the front wall surface of the housing 101,
The closing member 402 and the water valve housing 401 are pivotally fitted,
The second partition plate 403 is slidably fitted to the housing 101,
Limestone slurry processing equipment used for density measurement for thermal power plants, including A limestone slurry processing apparatus used for density measurement for thermal power plants according to claim 7,
The translator 301 is
a translation assist block 301a;
a first moving door 301b;
a second moving door 301c;
The translation assist block 301a is provided on the side of the valve housing 304,
The first moving door 301b is provided at the lower end of the translation assisting block 301a,
The second moving door 301c is provided on the side of the first moving door 301b,
The translation assist block 301a is fixedly connected to the valve housing 304,
The first moving door 301b and the translation assisting block 301a are slidably fitted,
The second moving door 301c is slidably fitted to the translation assisting block 301a,
Limestone slurry processing equipment used for density measurement for thermal power plants. A limestone slurry processing apparatus used for density measurement for thermal power plants according to claim 8,
The oscillator 303 is
a first swing block 303a;
a second swing block 303b;
a third swing block 303c;
a fourth swing block 303d;
a cavity 303e;
a slide column 303f;
a first engagement block 303g;
a second engagement block 303h;
The cavity 303e is formed between the first swing block 303a and the second swing block 30.
3b, respectively opened in the third swing block 303c and the fourth swing block 303d;
The first swing block 303a is provided on the side surface of the valve housing 304,
The second swing block 303b is provided on the side surface of the valve housing 304,
The third swing block 303c is provided on the side surface of the valve housing 304,
The fourth swing block 303d is provided on the side surface of the valve housing 304,
The slide columns 303f are respectively provided inside the cavities 303e,
The first engagement block 303g is provided at the lower end of the second swing block 303b,
The second engagement block 303h is provided at the lower end of the third swing block 303c,
The first swing block 303a and the support column 302 are rotationally fitted,
The second swing block 303b and the support column 302 are rotationally fitted,
The third swing block 303c and the support column 302 are rotationally engaged,
The fourth swing block 303d and the support column 302 are engaged in rotation,
The two slide columns 303f are fixedly connected to the first moving door 301b,
The remaining slide column 303f is fixedly connected to the second moving door 301c,
The first engagement block 303g and the second swing block 303b are fixedly connected,
The second engagement block 303h is fixedly connected to the third swing block 303c,
Limestone slurry processing equipment used for density measurement for thermal power plants. A limestone slurry processing apparatus used for density measurement for thermal power plants according to claim 8,
The closure member 402 is
a push handle 402a;
a push door 402b;
a push groove 402c;
a piping block 402d;
The push door 402b is provided inside the water valve housing 401,
The push groove 402c is formed in the water valve housing 401,
The piping block 402d is provided on the inner wall of the water valve housing 401,
The push handle 402a is provided in the push groove 402c,
The push handle 402a and the piping block 402d are fixedly connected,
The push door 402b is fixedly connected to the piping block 402d.
Limestone slurry processing equipment used for density measurement for thermal power plants.

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