CN217716906U - Water distribution test data collection device and fire control nozzle full-automatic water distribution test system - Google Patents

Abstract

The utility model belongs to the technical field of the fire control product detects, the utility model provides a water distribution test data collection device. Wherein, water distribution test data collection device includes: the water tank comprises an upper frame assembly, a water tank body, at least one electromagnetic valve, a weighing inclined water tank, a weighing module and a base; the weighing module is fixed with the base, the upper part of the weighing module is connected with the weighing inclined water tank, an opening above the weighing inclined water tank is positioned below the water tank body, the edge of the water tank body and the top of a frame of the base are mutually fixed after being matched, a water outlet is arranged at the bottom of each water collecting box in the water tank body, and the opening above the weighing inclined water tank is over against the lower part of each water outlet; the upper frame component is matched with the top of the edge of the water tank body, and the upper frame component is provided with a wedge-shaped knife-shaped opening structure inclined towards the inside of the water tank body. In addition, this application still provides a full-automatic water distribution test system of fire control shower nozzle.

Description

Water distribution test data collection device and fire control nozzle full-automatic water distribution test system

Technical Field

The utility model belongs to the technical field of the fire control product detects, especially, relate to a water distribution test data collection device and full-automatic water distribution test system of fire control shower nozzle.

Background

In the existing water distribution test process, a plurality of water distribution test data collecting devices placed on the ground are used for collecting water mist sprayed by nozzles, water quantity data in each water distribution test data collecting device is measured in a mode of sequentially measuring the volume or the liquid level height of liquid in each water distribution test data collecting device, so that each measurement needs to be completed manually, and the data collection of the water distribution test is a very labor-consuming process.

The liquid level height in the middle of each water distribution test data collection device is measured by the liquid level meter just for collecting the water distribution test data in the prior art, but the liquid level height is influenced by factors such as uneven temperature expansion of the inner wall of the water distribution test data collection device, damage of the inner wall, remaining of the residual water of the previous test and the like, so that the actual water quantity is difficult to accurately reflect by the liquid level height in each water distribution test data collection device, and the measurement precision of the liquid level meter is low, and the precision of the water distribution test is also reduced.

In addition, the water distribution test data collection device in the prior art is usually made of a square frame and a partition plate, the partition plate and the top surface of the frame are provided with a certain width interval, the liquid sprayed by the water mist can splash at the interval, the splashed splash can splash into a plurality of nearby water distribution test data collection devices, the liquid which is not collected by the water distribution test data collection device is counted into the water collection amount, and the factor influencing the accuracy of the existing water distribution test is also one of the factors.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems of the prior art that the data collection process is complicated, the liquid level meter measurement accuracy is low and the water distribution test data collection device interval influences the measurement accuracy, the utility model aims at providing a water distribution test data collection device and a full-automatic water distribution test system of fire sprinkler, use this water distribution test data collection device and this full-automatic water distribution test system of fire sprinkler, can accomplish whole data automatically and collect the process, and the measuring mode is more intelligent.

The utility model provides a water distribution test data collection device, include:

the base comprises a horizontally arranged beam and a vertically arranged frame;

the weighing module is fixed with the cross beam;

the upper part of the weighing inclined water tank is opened, the upper part of the weighing module is connected with the bottom of the weighing inclined water tank, and the bottom of the weighing inclined water tank is provided with an electromagnetic valve for controlling water drainage;

the edge of the water tank body is matched with the top of the frame of the base and then fixed with each other, a water outlet is formed in the bottom of the water tank body, a drainage pipeline is connected below each water outlet, and each drainage pipeline is provided with an electromagnetic valve for controlling drainage; and

and the upper frame component is matched with the top of the edge of the water tank body and is provided with a wedge-shaped knife-shaped opening structure which inclines towards the inside of the water tank body.

According to an embodiment of the application, the inside of water tank body is equipped with the baffle, the baffle will this internal space of water tank is cut apart into two at least water-collecting box, and the bottom of every water-collecting box is provided with a outlet, and a drainage pipe is connected to every outlet below, every drainage pipe sets up one respectively and is used for controlling the solenoid valve of drainage.

According to an embodiment of the present application, the wedge-shaped knife-like mouth structure includes:

a fitting part connected to a top edge of the tank body, the fitting part extending along the top edge of the tank body;

the assembling part is vertically aligned with the outer side edge of the water tank body, and the bottom of the assembling part is connected with the outer side edge of the assembling part; and

and a slope part which is uniformly inclined from the top of the assembly part to the inner side edge of the assembly part.

According to one embodiment of the present application, the fitting portion and the rim of the tank body are detachably coupled.

According to an embodiment of the application, this internal baffle of water tank is the cross, the baffle will the square water-collecting box of four equal divisions is split into to the inside of water tank body.

According to an embodiment of the present application, a bottom plate of each of the water collecting boxes is inclined toward the drain opening provided thereto.

According to one embodiment of the application, the outer side edges of the upper frame assembly, the water tank body and the base are of straight structures, and the outer side edges of the water distribution test data collecting device are vertically aligned.

According to one embodiment of the application, the overall shape of the water distribution test data collecting device on the horizontal plane is square.

According to one embodiment of the present application, at least one adjustable mechanism for adjusting the horizontal position and height and at least one pulley mechanism for facilitating the movement of the base are disposed around the base.

According to one embodiment of the application, one of said adjustable mechanisms and one of said pulley mechanisms are formed by a common caster.

According to one embodiment of the application, at least one level meter is arranged at the edge of the base and/or the weighing module and used for detecting whether the water distribution test data collection device is kept horizontal or not.

The utility model also provides a full-automatic water distribution test system of fire control shower nozzle, include:

a spray unit comprising a frame, at least one ceiling nozzle, and a water supply mechanism;

at least one water distribution test data collection device which is arranged below the spraying unit; and

and the main control unit is respectively connected with the spraying unit and the water distribution test data collecting device, and is used for controlling the opening and closing of the spraying unit and controlling the work of the electromagnetic valve and/or the weighing module in the water distribution test data collecting device.

According to one embodiment of the application, the main control unit is electrically connected with the spraying unit and the water distribution test data collection device through data lines.

According to one embodiment of the application, a plurality of water distribution test data collecting devices are spliced and arranged into a square structure.

The utility model has the advantages that:

1. compared with a normal common box, the wedge-shaped knife-shaped opening can reduce most of splashed water. The wedge-shaped knife-like opening provides an inclined ramp at the top, so that the splashing water drops fall down the ramp and flow back into the collecting box.

2. Because the edge of the wedge-shaped knife-shaped opening is assembled in a detachable mode, the maintenance cost and time can be greatly reduced. Compared with other components, the edge of the wedge-shaped knife-shaped opening positioned at the outer side is inevitably damaged in the moving and assembling processes, and the edge of the wedge-shaped knife-shaped opening of the water distribution test data collection device can be detached and maintained independently when only the edge is damaged by adopting a detachable mode. Therefore, compared with the maintenance or replacement of the whole water distribution test data collecting device, the design can greatly reduce the cost and time.

3. The water distribution test data collection device adopts a design of Fu Ma Lun and a level meter, and whether the whole water collection platform is positioned on the horizontal ground or not can be ensured due to the existence of the level meter.

4. The whole conveying and weighing process is supervised by the main control unit, and the main control unit can control the conveying by controlling the opening and closing of the electromagnetic valve on the conveying port; and the weighing readings of the weighing box are synchronously displayed on the main control unit, and when the weighing is finished, the driving end can control the drainage by controlling the electromagnetic valve below the weighing box.

5. The weighing inclined water tank and the weighing module sequentially weigh, and have the advantages that each weighing corresponds to a corresponding spraying test, the accumulative error of accumulative weighing is avoided, and the weighing accuracy is greatly improved. The weighing accuracy is significantly higher in turn than for a level gauge.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1a is a front view of the water distribution test data collection device of the present invention, and fig. 1b is a top view of the water distribution test data collection device of the present invention;

fig. 2 is an exploded view of the technical unit of the present invention.

FIG. 3 is a schematic view of Ford Ma Jiaolun.

Fig. 4 is a sectional view of the upper rim assembly and the tank body.

Fig. 5 is a schematic view of the fire sprinkler full-automatic water distribution test system of the utility model.

The reference numbers illustrate:

1-a top frame assembly;

2-the water tank body;

3-an electromagnetic valve;

4-weighing the inclined water tank;

5-a weighing module;

6-a base;

7-a separator;

8-a water outlet;

9-a water collecting box;

10-a water distribution test data collecting device;

11-a fitting part;

12-a splicing section;

13-a landslide section;

20-a spraying unit;

21-a frame;

22-ceiling nozzle;

23-a water supply mechanism;

30-master control unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "left", "right", "center", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; either directly or indirectly through intervening media, or through both elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Exemplary embodiments

As shown in fig. 1a, 1b and 2, the present exemplary embodiment provides a water distribution test data collecting apparatus 10 including: go up frame subassembly 1, water tank body 2, at least one solenoid valve 3, oblique basin 4, weighing module 5 and base 6 of weighing. In the exemplary embodiment, the outer edges of the upper frame assembly 1, the tank body 2 and the base 6 are straight, and the outer edges of the water distribution test data collection device 10 are vertically aligned.

The base 6 comprises a horizontally arranged beam and a vertically arranged frame. Weighing module 5 is fixed mutually with the crossbeam, and weighing module 5's top is connected with weighing inclined trough 4, and weighing inclined trough 4's top is opened, and weighing inclined trough 4's the uncovered below that is located water tank body 2 in top, and weighing inclined trough 4's bottom is equipped with a solenoid valve 3 that is used for controlling the drainage. This solenoid valve 3 is opened after weighing at every turn, and the liquid evacuation in the oblique basin 4 of will weighing, and the oblique basin 4 of weighing after the evacuation can bear the liquid volume in next water distribution test data collection device 10, and the oblique basin 4 of will weighing is empty in weighing promptly each time to further zero clearing weighing module 5's numerical value, can not accumulative total error value causes the influence to the water distribution experiment.

In the present exemplary embodiment, at least one adjustable mechanism for adjusting the horizontal position and height, and at least one pulley mechanism for facilitating the movement of the base 6 are provided around the base 6. An adjustable mechanism and a pulley mechanism share one horse caster. The special structure of the Fuma wheel makes fixing and convenient moving possible, as shown in figure 3, the Fuma wheel mainly comprises a wheel and a fixed platform driven by a gear, and when moving is needed, the wheel of the Fuma wheel Ma Lun can provide convenience; when the horse wheel needs to be fixed, the gear on the horse wheel can be twisted to enable the platform below to contact the ground, so that the effect of fixing the whole device is achieved. Therefore, in the case of securing a level ground by a level, the water distribution test data collecting apparatus 10 can be quickly moved to a desired position, and it is also extremely convenient when a plurality of water distribution test data collecting apparatuses 10 are required to be spliced due to its square configuration. When the water distribution test data collection device 10 is spliced and needs to be fixed, the Fu Ma Lun can also provide stability.

In the present exemplary embodiment, at least one level gauge is provided at the edge of the base 6 and/or the weighing module 5 for detecting whether the water distribution test data collection device 10 is kept horizontal.

The edge of water tank body 2 and the frame top of base 6 are mutually fixed after the cooperation, the inside of water tank body 2 is equipped with baffle 7, baffle 7 is divided into two at least water-collecting box 9 with the space in the water tank body 2, the bottom of every water-collecting box 9 is provided with an outlet 8, a drainage pipe is connected to every outlet 8 below, every drainage pipe sets up an solenoid valve 3 that is used for controlling the drainage respectively, the below of every outlet 8 is just uncovered to the top of weighing oblique basin 4. In the present exemplary embodiment, the floor of each catchment box 9 is inclined towards the drain 8 in which it is arranged, so that the liquid in the catchment box 9 can flow entirely into the weighing flume 4 below.

In the present exemplary embodiment, the overall shape of the water distribution test data collecting apparatus 10 in the horizontal plane is a square. The partition plate 7 in the water tank body 2 is in a cross shape, and the partition plate 7 divides the inside of the water tank body 2 into four equally-divided square water collecting boxes 9.

The top of the edge of the upper frame component 1 is matched with the top of the edge of the water tank body 2, and the upper frame component 1 is provided with a wedge-shaped knife-shaped opening structure which inclines towards the inside of the water tank body 2. In the present exemplary embodiment, as shown in fig. 4, the wedge-shaped knife-shaped mouth structure includes: and a fitting part 11 connected to a top edge of the tank body 2, the fitting part 11 extending along the top edge of the tank body 2. And a splicing part 12 vertically aligned with the outer side edge of the water tank body 2, wherein the bottom of the splicing part 12 is connected with the outer side edge of the assembling part 11. And a slope part 13 which is uniformly inclined from the top of the assembling part 12 to the inner side edge of the assembling part 11. Compared with a normal common box, the wedge-shaped knife-shaped opening can reduce most of splashed water. The wedge-shaped opening provides an inclined ramp at the top, so that the splashed water droplets fall there, following the slope, back into the collecting box 9. And if the edge of the normal quadrangle is adopted, the sputtered water drops are easy to accumulate at the edge of the water collecting box 9, and the error value of the spraying test is improved.

In the present exemplary embodiment, the fitting portion 11 and the edge of the tank body 2 are detachably connected. Because the edge of the wedge-shaped knife-shaped opening is assembled in a detachable mode, the maintenance cost and time can be greatly reduced. Compared with other components, the edge of the wedge-shaped knife-shaped opening positioned at the outer side is inevitably damaged in the moving and assembling processes, and the edge of the wedge-shaped knife-shaped opening of the water distribution test data collection device 10 can be detached and maintained independently by adopting a detachable mode when only the edge is damaged. Therefore, such a design can greatly reduce the cost and time as compared to repairing or replacing the entire water distribution test data collection device 10.

As shown in fig. 5, the present exemplary embodiment further provides a full-automatic water distribution test system for a fire sprinkler, including: a spray unit 20 comprising a frame 21, at least one ceiling nozzle 22 and a water supply 23. And at least one water distribution test data collection device 10 which is arranged below the spraying unit 20. And the main control unit 30 is respectively connected with the spraying unit 20 and the water distribution test data collection device 10, and is used for controlling the opening and closing of the spraying unit 20 and controlling the work of the electromagnetic valve 3 and/or the weighing module 5 in the water distribution test data collection device 10.

In the present exemplary embodiment, the main control unit 30 is electrically connected to the spraying unit 20 and the water distribution test data collection device 10 through data lines.

In the exemplary embodiment, the overall shape of the water distribution test data collection device 10 on the horizontal plane is a square, the partition plate 7 in the tank body 2 is a cross, and the partition plate 7 divides the inside of the tank body 2 into four equally divided square water collection boxes 9. The water distribution test data collection devices 10 are spliced and arranged to form a square structure. Because the outer edges of the whole water distribution test data collecting device 10 are of a straight structure and the sizes of all the water distribution test data collecting devices 10 are of a square structure, when the water distribution test data collecting device is installed, the two water distribution test data collecting devices 10 can be well spliced together.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The embodiment provides a fire-fighting nozzle full-automatic water distribution test system comprising 16 water distribution test data collecting devices 10 which are arranged in 4*4. The outer edges of the 16 water distribution test data collection devices 10 are in a straight structure and the sizes of all the water distribution test data collection devices 10 are in a square structure, so that when the water distribution test data collection devices are installed, the two water distribution test data collection devices 10 can be spliced together almost perfectly. Therefore, the tops of the wedge-shaped knife-shaped opening structures of the water distribution test data collection device 10 are almost in seamless butt joint after splicing, and most of splashed water can be reduced. The sliding slope part 13 of the wedge-shaped knife-shaped opening structure is uniformly inclined from the top of the assembling part 12 to the inner side edge of the assembling part 11, and splashed water drops fall to the sliding slope part and flow back to the water collecting box 9 along the slope.

The partition plate 7 in the water tank body 2 is in a cross shape, and the partition plate 7 divides the inside of the water tank body 2 into four equally-divided square water collecting boxes 9. Each of the 16 water distribution test data collection devices 10 has 4 water collection boxes 9, so that 8*8 water collection boxes 9 form a matrix, and each water collection box 9 corresponds to each data unit in one data matrix. The electromagnetic valve 3 in each water distribution test data collection device 10, the electromagnetic valve 3 of the weighing inclined water tank 4 and the weighing module 5 are connected with the main control unit 30 through data lines and the like.

The spraying unit 20 adopts a frame 21 erected in the existing water distribution test, a water pipe is erected at the top of the frame 21, a tested object is simulated, and a plurality of suspended ceiling nozzles 22 are installed at corresponding intervals, angles and positions on the water pipe and used for simulating the real spraying state of the tested object. The rear end of the water pipe is connected to a water supply mechanism 23, and the water supply mechanism 23 uses an existing water pump. After the water pump is started, water flows enter the top of the water pipe and spray water into the water distribution test data collection device 10 below through the ceiling nozzle 22, the water distribution test data collection device 10 collects water in sprayed water mist, different water collection boxes 9 represent the water spraying conditions of the water mist at different positions, and the water distribution condition of the measured object is evaluated through the water spraying data.

After the water distribution test device is arranged, the concrete operation of the water distribution test can be started.

First, the main control unit 30 turns on the water supply mechanism 23, and the water supply mechanism 23 pumps tap water into the ceiling nozzle 22 through a water pipe. The water is sprayed by the ceiling nozzle 22 to form water mist, and the whole water distribution test data collection device 10 collects tap water in the water mist. After the time specified by the test is reached, the main control unit 30 closes the water supply mechanism 23, and at this time, the water distribution test data collection device 10 has completed the water quantity collection step in the whole water distribution test.

The main control unit 30 is internally provided with a data matrix corresponding to each water collecting box 9 in the water distribution test data collecting device 10. In the embodiment, 4*4 water distribution test data collecting devices 10 are used, that is, 64 water collecting boxes 9 form the 8*8 data matrix. For convenience of explanation, the sump case 9 positioned at the upper left in each sump case 9 is defined as a first sump case 9, the sump case 9 positioned at the upper right is defined as a second sump case 9, the sump case 9 positioned at the lower left is defined as a third sump case 9, and the sump case 9 positioned at the lower right is defined as a fourth sump case 9.

After the above definition and the initialization of the data matrix are completed, the main control unit 30 opens the electromagnetic valve 3 on the water outlet 8 at the bottom of the first water collecting box 9 in each water distribution test data collecting device 10, the liquid in the first water collecting box 9 flows into the weighing inclined water tank 4 below, and at this time, the electromagnetic valve 3 at the bottom of the weighing inclined water tank 4 is in a closed state. The main control unit 30 starts the weighing module 5, weighs the weight of the liquid in the weighing inclined water tank 4, and records the weight in the unit of the corresponding data matrix by the main control unit 30. After the weighing of the water amount in the first water collecting box 9 is completed, the main control unit 30 opens the electromagnetic valve 3 at the water outlet 8 of the weighing inclined water tank 4 to empty the liquid in the weighing inclined water tank 4, and the main control unit 30 performs the zero setting operation on the weighing module 5. Therefore, the weighing at each time can be more accurate, and the generation of accumulated errors is avoided.

After the first water collecting box 9 in each water distribution test data collecting device 10 is weighed, the main control unit 30 sequentially weighs the weight of the liquid in the second water collecting box 9, the third water collecting box 9 and the fourth water collecting box 9 according to the steps until the liquid in all the water collecting boxes 9 in the water distribution test data collecting device 10 is weighed, and a data matrix for recording all weight data is obtained, namely the data collection of the water distribution test is completed.

Above be the whole process of water distribution test, the utility model discloses especially, data collection link wherein has improved emphatically. In the data collection process, batch weighing operation is performed for four times in total, so that the time of a data collection link and the consumed manpower are shortened. Wherein, the times of batch weighing operation correspond to the number of the water collecting boxes 9 in each water distribution test data collecting device 10. For example, if only two water collection boxes 9 are included in the water distribution test data collection device 10, a complete data matrix can be obtained by performing two batch weighing operations in total.

To sum up, the utility model discloses following beneficial effect has:

1. compared with a normal common box, the wedge-shaped knife-shaped opening can reduce most of splashed water. The wedge-shaped knife-like opening provides an inclined ramp at the top, so that the splashing water drops fall down the ramp back into the collecting box 9.

2. Because the edge of the wedge-shaped knife-shaped opening is assembled in a detachable mode, the maintenance cost and time can be greatly reduced. Compared with other components, the edge of the wedge-shaped knife-shaped opening positioned at the outer side is inevitably damaged in the moving and assembling processes, and the edge of the wedge-shaped knife-shaped opening of the water distribution test data collection device 10 can be detached and maintained independently by adopting a detachable mode when only the edge is damaged. Therefore, such a design can greatly reduce the cost and time as compared to repairing or replacing the entire water distribution test data collection device 10.

3. The water distribution test data collection device 10 adopts a design of Fu Ma Lun plus a level meter, and whether the whole water collection platform is positioned on the horizontal ground or not can be ensured due to the existence of the level meter.

4. The whole conveying and weighing process is supervised by the main control unit 30, and the main control unit 30 can control the conveying by controlling the opening and closing of the electromagnetic valve 3 on the conveying port; and the weighing readings of the weighing boxes are synchronously displayed on the main control unit 30, and when the weighing is finished, the driving end can control the drainage by controlling the electromagnetic valve 3 below the weighing boxes.

5. The advantage that oblique basin 4 and weighing module 5 of weighing weigh in proper order all is corresponding spraying experiment in weighing at every turn to avoid coming from the accumulative total error of weighing, improve the accuracy of weighing greatly. The weighing accuracy is significantly higher in turn than for a level gauge.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, improvements, equivalents, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (14)

1. The utility model provides a water distribution test data collection device which characterized in that includes:

the base (6) comprises a horizontally arranged beam and a vertically arranged frame;

the weighing module (5) is fixed with the cross beam;

the weighing inclined water tank (4) is open above the weighing inclined water tank (4), the upper part of the weighing module (5) is connected with the bottom of the weighing inclined water tank (4), and the bottom of the weighing inclined water tank (4) is provided with an electromagnetic valve (3) for controlling drainage;

the edge of the water tank body (2) is matched with the top of the frame of the base (6) and then fixed with each other, a water outlet (8) is formed in the bottom of the water tank body (2), a drainage pipeline is connected below each water outlet (8), and each drainage pipeline is provided with an electromagnetic valve (3) used for controlling drainage; and

the upper frame component (1) is matched with the top of the edge of the water tank body (2), and the upper frame component (1) is provided with a wedge-shaped knife-shaped opening structure which inclines towards the inside of the water tank body (2).

2. The water distribution test data collection device according to claim 1, wherein a partition (7) is provided inside the water tank body (2), the partition (7) divides the space inside the water tank body (2) into at least two water collecting boxes (9), a water outlet (8) is provided at the bottom of each water collecting box (9), a water discharge pipe is connected below each water outlet (8), and each water discharge pipe is provided with one solenoid valve (3) for controlling water discharge.

3. The water distribution test data collection device of claim 1, wherein the wedge-shaped knife-shaped opening structure comprises: a fitting part (11) connected to a top edge of the tank body (2), the fitting part (11) extending along the top edge of the tank body (2);

the assembling part (12) is vertically aligned with the outer side edge of the water tank body (2), and the bottom of the assembling part (12) is connected with the outer side edge of the assembling part (11); and

and a slope part (13) which is uniformly inclined from the top of the assembly part (12) to the inner side edge of the assembly part (11).

4. The water distribution test data collection device according to claim 3, wherein the fitting part (11) is detachably connected with the edge of the water tank body (2).

5. The water distribution test data collection device according to claim 1, wherein the partition plate (7) in the water tank body (2) is cross-shaped, and the partition plate (7) divides the inside of the water tank body (2) into four equally divided square water collecting boxes (9).

6. The water distribution test data collection device according to claim 2, wherein the bottom plate of each water collection box (9) is inclined toward the water outlet (8) provided therein.

7. The water distribution test data collection device according to claim 1, wherein the outer edges of the upper frame assembly (1), the water tank body (2) and the base (6) adopt a straight structure, and the outer edges of the water distribution test data collection device (10) are vertically aligned.

8. The water distribution test data collection device according to claim 1, wherein the overall shape of the water distribution test data collection device (10) in a horizontal plane is a square.

9. The water distribution test data collection device according to claim 1, wherein at least one adjustable mechanism for adjusting the horizontal position and height and at least one pulley mechanism for facilitating the movement of the base (6) are arranged around the base (6).

10. The water distribution test data collection device of claim 9, wherein one adjustable mechanism and one pulley mechanism share a common caster.

11. The water distribution test data collection device according to claim 10, wherein at least one level gauge is arranged at the edge of the base (6) and/or the weighing module (5) and is used for detecting whether the water distribution test data collection device (10) is kept horizontal.

12. The utility model provides a full-automatic water distribution test system of fire control shower nozzle which characterized in that includes:

a spray unit (20) comprising a frame (21), at least one ceiling nozzle (22) and a water supply mechanism (23);

at least one water distribution test data collection device (10) according to any one of claims 1 to 11, placed below the sprinkling unit (20); and

and the main control unit (30) is respectively connected with the spraying unit (20) and the water distribution test data collecting device (10), and is used for controlling the opening and closing of the spraying unit (20) and controlling the work of the electromagnetic valve (3) and/or weighing module (5) in the water distribution test data collecting device (10).

13. The fire sprinkler full-automatic water distribution test system according to claim 12, wherein the main control unit (30) is electrically connected with the spraying unit (20) and the water distribution test data collection device (10) through data lines.

14. The fire sprinkler full-automatic water distribution test system according to claim 12, wherein a plurality of the water distribution test data collecting devices (10) are spliced and arranged to each other in a square structure.

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