CN214333511U

CN214333511U - Rubber ball cleaning device

Info

Publication number: CN214333511U
Application number: CN202022434565.4U
Authority: CN
Inventors: 张健; 黄继军; 李其安
Original assignee: Guangxi Investment Group Beihai Power Generation Co Ltd
Current assignee: Guangxi Investment Group Beihai Power Generation Co Ltd
Priority date: 2020-10-28
Filing date: 2020-10-28
Publication date: 2021-10-01
Anticipated expiration: 2030-10-28

Abstract

The utility model is suitable for an industrial water circulating system washs technical field, provides a gluey ball belt cleaning device, is equipped with the cold heat exchanger who washs gluey ball by inside, locates the receipts ball ware mechanism of cold heat exchanger cooling water outlet end for carry, collect and replace the circulation mechanism who washs gluey ball, differential pressure measurement mechanism, control mechanism and the secondary filter screen subassembly component of locating cold heat exchanger's the end of intaking are constituteed. The cleaning rubber ball enters the cold-heat exchanger under the driving of the circulating water flow, scrubs the silt dirt in the heat transfer pipe under the action of the pressure difference of the circulating water inlet and the circulating water outlet, and wipes the inner wall of the heat transfer pipe once, so that the silt dirt on the inner wall of the cooling pipe is brought out along with the water flow, and the cold-heat exchanger is continuously cleaned by the reciprocating circulation. The utility model discloses can prevent the dust granule of the suspension of circulating water and be killed the algae fungus class and form glutinous mud soft dirt deposit on cold and heat exchanger's heat transfer pipe inner wall.

Description

Rubber ball cleaning device

Technical Field

The utility model belongs to the technical field of industry water circulating system washs, especially, relate to a rubber ball belt cleaning device.

Background

Pure water hardly exists in natureNatural water is in contact with the external environment all the time during the circulation of nature, and therefore the water contains different components and different amounts of impurities. In industrial production, a large amount of hot water is produced. Taking a circulating cooling water system as an example, Ca in water is generated during the heating process of water²⁺、Mg²⁺Metal ions and CO as impurities₃ ^2-、HCO₃ ^-、SO₄ ^2-、Cl^-、NO₃ ^-When the impurity anions are combined together due to evaporation and concentration, CaCO can be formed₃、MgCO₃、CaSO₄、MgSO₄Scaling; meanwhile, the circulating cooling water system can not avoid dust or other raw material dust falling on the surface, and the dust return to the circulating water after deposition and attach to the inner wall of a heat transfer pipe of the condenser to form hard scale; on the other hand, the water temperature and the pH value of the circulating cooling water are suitable for the propagation and growth of most microorganisms, and with the continuous circulating evaporation of the circulating cooling water, the nutrient source in the water is increased, so that the mass propagation of the microorganisms is promoted. The microorganisms are mixed with the sludge to form a biological slime and finally form a biological scale. These fouls adhere to the heat transfer surface, resulting in low thermal efficiency, clogging of the heat exchanger, rise in pump pressure, decrease in flow rate, and accumulation of sludge, which seriously affect the normal operation of the equipment, accompanied by increased energy consumption, increased maintenance, and increased pollutant emissions.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the utility model is to provide a rubber ball belt cleaning device aims at solving the problem that mentions in the background art.

The embodiment of the utility model provides a realize like this, a rubber ball belt cleaning device, rubber ball belt cleaning device includes:

a cold-heat exchanger with cleaning rubber balls inside;

the ball collector mechanism is arranged at the cooling water outlet end of the cold-heat exchanger and is used for separating the cleaning rubber balls from the cooling water;

the circulating mechanism is used for conveying, collecting and replacing the cleaning rubber balls;

the pressure difference measuring mechanism is used for detecting the pressure difference value at the ball receiver mechanism in real time so as to monitor the number of the cleaning rubber balls at the ball receiver mechanism;

and the control mechanism is used for monitoring and controlling the operation of the rubber ball cleaning device.

Preferably, the ball receiver mechanism includes:

the ball collector shell is communicated with the cooling water outlet end of the cold-heat exchanger;

the ball outlet is arranged on the ball collector shell;

the ball collecting net is obliquely arranged in the ball collector shell and is used for guiding the cleaning rubber balls in the cooling water flowing through the ball collecting net to the ball outlet when being connected with the ball outlet;

a ball net drive assembly for adjusting the tilt angle of the ball net;

the observation hole is arranged on the ball receiver shell and used for observing the internal condition of the ball receiver shell;

and a baffle for generating a vortex inside the ball collector housing.

Preferably, the circulation mechanism includes:

the ball inlet pipe is communicated with the ball collector mechanism;

the inlet valve is arranged on the ball inlet pipe;

the rubber ball circulation monitor is arranged on the ball inlet pipe and used for monitoring the condition that the cleaning rubber balls enter the ball collector mechanism;

the rubber ball circulating pump is used for pumping the cleaning rubber balls separated by the ball collector mechanism;

the motor is used for driving the rubber ball circulating pump to operate;

the ball collector is used for collecting the cleaning rubber balls pumped by the rubber ball circulating pump; the ball collector is provided with a top cover and is used for adding cleaning rubber balls into the ball collector or taking out the cleaning rubber balls in the ball collector;

the exhaust valve is arranged on the ball collector;

the drainage valve is arranged on the ball collector;

one end of the ball injection pipe is communicated with the ball collector, and the other end of the ball injection pipe is communicated with the water inlet end of the cold-heat exchanger;

the outlet valve is arranged on the ball injection pipe;

and the base is used for supporting the rubber ball circulating pump and the ball collector.

Preferably, the ball collector includes:

a ball collector housing;

the ball collector inlet is arranged on the ball collector shell and is communicated with the rubber ball circulating pump through a pipeline;

the ball collector outlet is arranged on the ball collector shell and communicated with the ball injection pipe;

the exhaust port is arranged on the ball collector shell and is communicated with the exhaust valve;

the water outlet is arranged on the ball collector shell and communicated with the water discharge valve;

the ball collecting basket is used for collecting the cleaning rubber balls pumped by the rubber ball circulating pump;

the switching valve is used for switching the running state of the ball collector;

the ball collector driving component is used for driving the switching valve to operate;

the check valve is used for preventing the cleaning rubber balls collected by the ball collecting basket from flowing back to the rubber ball circulating pump.

Preferably, the differential pressure measuring mechanism includes:

the high-pressure joint is communicated with the ball collector mechanism;

the low-pressure joint is communicated with the ball collector mechanism;

a differential pressure transmitter in communication with the high pressure fitting and the low pressure fitting;

the flushing head is communicated with the differential pressure transmitter through a pipeline;

and the flushing valve is arranged on a pipeline for communicating the flushing head with the differential pressure transmitter.

Preferably, the control mechanism includes:

a logic control unit, in which a control program is stored; the ball collecting device mechanism, the circulating mechanism and the differential pressure measuring mechanism are all electrically connected with the logic control unit;

the control panel is provided with a control switch for triggering a control function;

an alarm component; the logic control unit sends out an alarm instruction when the rubber ball cleaning device fails, and the alarm assembly receives the alarm instruction and sends out an alarm signal.

Preferably, a backwashing program is included in the control program.

Preferably, the rubber ball cleaning device further comprises a secondary filter screen assembly, which is arranged at the water inlet end of the cold-heat exchanger and used for filtering impurities entering the water of the cold-heat exchanger.

The embodiment of the utility model provides a pair of gluey ball belt cleaning device comprises inside cold heat exchanger, receipts ball ware mechanism, circulation mechanism, differential pressure measurement mechanism, control mechanism and the secondary filter screen subassembly that is equipped with the washing gluey ball. The cleaning rubber ball enters the cold-heat exchanger under the driving of the circulating water flow, scrubs the silt dirt in the heat transfer pipe under the action of the pressure difference of the circulating water inlet and the circulating water outlet, and wipes the inner wall of the heat transfer pipe once, so that the silt dirt on the inner wall of the cooling pipe is brought out along with the water flow, and the cold-heat exchanger is continuously cleaned by the reciprocating circulation. The utility model discloses can prevent the dust granule of the suspension of circulating water and be killed the algae fungus class and form glutinous mud soft dirt deposit on cold and heat exchanger's heat transfer pipe inner wall.

Drawings

Fig. 1 is a schematic structural view of a rubber ball cleaning device provided in an embodiment of the present invention;

fig. 2 is a schematic structural view of a ball collector mechanism provided in the embodiment of the present invention;

fig. 3 is a schematic structural diagram of a circulation mechanism according to an embodiment of the present invention;

fig. 4 is a schematic partial structural view of a circulation mechanism according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a ball collector provided in the embodiment of the present invention;

fig. 6 is a schematic structural diagram of a differential pressure measurement mechanism according to an embodiment of the present invention.

In the drawings: 1. cleaning the rubber ball; 2. a ball collector mechanism; 21. a ball receiver housing; 22. an observation hole; 23. a baffle; 24. a bearing; 25. a ball outlet; 26. collecting the ball net; 27. a ball screen drive assembly; 3. a circulating mechanism; 31. a rubber ball circulating pump; 32. a motor; 33. a ball collector; 331. a ball collector housing; 332. a ball collector drive assembly; 333. an outlet of the ball collector; 334. an inlet of the ball collector; 335. a top cover; 336. an exhaust port; 337. a water outlet; 338. a ball collecting basket; 339. a check valve; 3310. a switching valve; 34. an inlet valve; 35. an outlet valve; 36. an exhaust valve; 37. a rubber ball circulation monitor; 38. a drain valve; 39. a base; 5. a cold-heat exchanger; 6. a secondary screen assembly; 7. a differential pressure measuring mechanism; 71. a differential pressure transmitter; 72. a high-pressure joint; 73. a low pressure connection; 74. a rinsing head; 75. and (6) flushing the valve.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The following detailed description is provided for the specific embodiments of the present invention.

As shown in fig. 1, for the utility model discloses a glue ball belt cleaning device that an embodiment provided, glue ball belt cleaning device includes:

a cold-heat exchanger 5 with cleaning rubber balls 1 inside;

the ball collector mechanism 2 is arranged at the cooling water outlet end of the cold-heat exchanger 5 and is used for separating the cleaning rubber balls 1 into cooling water;

the circulating mechanism 3 is used for conveying, collecting and replacing the cleaning rubber balls 1;

the pressure difference measuring mechanism 7 is used for detecting the pressure difference value at the ball receiver mechanism 2 in real time so as to monitor the number of the cleaning rubber balls 1 at the ball receiver mechanism 2;

Specifically, the cleaning rubber ball 1 is the most important part of the whole rubber ball cleaning device, and is a round sponge ball body which is not easy to corrode and damage. The correct choice of the cleaning rubber ball 1 is very important and determines whether the rubber ball cleaning device can exert the maximum efficacy. In practical use, the cleaning rubber ball 1 enters the cold-heat exchanger 5 under the driving of water flow, and due to the pressure difference between the two ends of the cold-heat exchanger 5, the cleaning rubber ball 1 scrubs impurities such as silt and the like in the heat transfer pipe in the cold-heat exchanger 5 under the action of the pressure difference, and the scrubed impurities are carried out along with the water flow. The cleaning rubber balls 1 can flow out of the cold-heat exchanger 5 along with water flow, then are separated from water through the ball collector mechanism 2, the separated cleaning rubber balls 1 enter the circulating mechanism 3, a part of the circulating mechanism 3 which can be continuously used is conveyed to the cold-heat exchanger 5 again through the circulating mechanism 3, a part of the cleaning rubber balls 1 which can not be used is taken out and is supplemented with new cleaning rubber balls 1, and the supplemented new cleaning rubber balls 1 are conveyed to the cold-heat exchanger 5 under the action of the circulating mechanism 3. The utility model discloses still be provided with differential pressure measuring mechanism 7 in ball ware mechanism 2 departments of receiving, receive the pressure differential value of ball ware mechanism 2 departments through real-time detection, and then monitor and receive the 1 figure of washing rubber ball of ball ware mechanism 2 departments. The running state of the whole rubber ball cleaning device is monitored and regulated by a control mechanism, manual operation is rarely needed, the automation degree is high, and suspended dust particles in circulating water and killed algae fungi can be prevented from forming slime and soft dirt and depositing on the inner wall of the heat transfer pipe of the cold-heat exchanger 5.

As shown in fig. 2, as a preferred embodiment of the present invention, the ball receiver mechanism 2 includes:

a ball receiver shell 21 communicated with the cooling water outlet end of the cold-heat exchanger 5;

the ball outlet 25 is arranged on the ball collector shell 21;

a ball receiving net 26 obliquely arranged inside the ball collector housing 21 and connected with the ball outlet 25 for leading the cleaning rubber balls 1 in the cooling water flowing through the ball receiving net 26 to the ball outlet 25;

a ball net drive assembly 27 for adjusting the tilt angle of said ball net 26;

an observation hole 22 provided in the ball receiver housing 21 for observing the internal condition of the ball receiver housing 21;

a baffle 23 for generating a vortex flow inside the ball collector housing 21.

Specifically, the ball receiver shell 21 is made of Q235B steel and lined with rubber; the metal parts inside the ball receiver housing 21 are mostly made of stainless steel. The ball receiving net 26 is formed of a vertical grid, to which a net plate is attached, and this design maximizes the surface strength of the ball receiving net 26. The ball receiving net 26 has a semi-elliptical shape and is obliquely disposed inside the ball collector housing 21. The inclination angle of the ball net 26 is adjusted by the ball net driving unit 27 depending on the cooling water discharge condition of the heat exchanger 5. The ball net drive assembly 27 is formed by a thrust gear and is connected to the ball net 26 by the bearing 24, and the ball net drive assembly 27 is regulated by a control mechanism. When the ball collector mechanism 2 is operated, the cleaning rubber balls 1 flowing out of the cold heat exchanger 5 along with the water flow are separated from the water under the action of the ball collecting net 26, and when the inclined direction of the ball collecting net 26 faces the ball outlet 25, the cleaning rubber balls 1 are guided to the ball outlet 25 by the ball collecting net 26 to enter the circulating mechanism 3. The flow guide plate 23 can generate vortex flow to further guide the cleaning rubber balls 1 to the ball outlet 25 while preventing impurities from being retained on the periphery of the ball collecting net 26. The ball receiver shell 21 is further provided with an observation hole 22, so that personnel can observe the internal condition of the ball receiver shell 21 conveniently.

As shown in fig. 3 and 4, as a preferred embodiment of the present invention, the circulation mechanism 3 includes:

the ball inlet pipe is communicated with the ball collector mechanism 2;

an inlet valve 34 arranged on the ball inlet pipe;

the rubber ball circulation monitor 37 is arranged on the ball inlet pipe and used for monitoring the condition that the cleaning rubber balls 1 enter the ball collector mechanism 2;

the rubber ball circulating pump 31 is used for pumping the cleaning rubber balls 1 separated by the ball collector mechanism 2;

the motor 32 is used for driving the rubber ball circulating pump 31 to operate;

the ball collector 33 is used for collecting the cleaning rubber balls 1 pumped by the rubber ball circulating pump 31; the ball collector 33 is provided with a top cover 335 for adding the cleaning rubber ball 1 into the ball collector 33 or taking out the cleaning rubber ball 1 in the ball collector 33;

an exhaust valve 36 provided on the ball collector 33;

a drain valve 38 provided on the ball collector 33;

one end of the ball injection pipe is communicated with the ball collector 33, and the other end of the ball injection pipe is communicated with the water inlet end of the cold-heat exchanger 5;

the outlet valve 35 is arranged on the ball injection pipe;

and a base 39 for supporting the rubber ball circulating pump 31 and the ball collector 33.

In particular, although the cleaning rubber balls 1 can enter the ball inlet pipe under the action of the inclined ball receiving net 26 and the flow guide plate 23, part of the cleaning rubber balls 1 still need a certain amount of water for the rubber ball circulating pump 31 to be extracted from the ball collector mechanism 2. The cleaning rubber balls 1 entering the ball inlet pipe are conveyed to the ball injection pipe under the action of the rubber ball circulating pump 31, and in the process, the rubber ball circulating pump 31 needs to overcome the pressure difference between the ball collector mechanism 2 and the ball injection pipe and the lift loss in the circulating mechanism 3 (including a pipeline between the ball collector mechanism and the ball injection pipe). The rubber ball circulation pump 31 may be a double channel centrifugal pump with the main shaft loaded by a permanently lubricated groove ball bearing and the shaft seal in the form of a mechanical seal. Wherein the impeller adopts special design, guarantees that glueballs circulating pump 31 also can not cause glueballs circulating pump 31 to damage in transportation process under high-efficient operation. The rubber ball circulating pump 31 is driven by the motor 32 to operate, and the operation of the motor 32 is regulated and controlled by the control mechanism.

The cleaning rubber ball 1 is firstly conveyed to the ball collector 33 under the action of the rubber ball circulating pump 31, and water is used when the cleaning rubber ball 1 is pumped by the rubber ball circulating pump 31, so that the cleaning rubber ball 1 is separated from the water by the ball collector 33, the separated water can be discharged through the drainage valve 38, and the pressure inside the ball collector 33 can be adjusted through the exhaust valve 36. The damaged top cover 335 of the openable ball collector 33 in the cleaning rubber ball 1 is taken out and then a new cleaning rubber ball 1 is put in. The cleaning rubber balls 1 are conveyed to the water inlet end of the cold-heat exchanger 5 through the ball injection pipe under the action of the rubber ball circulating pump 31, and the cold-heat exchanger 5 is brushed again along with the water flow at the water inlet end of the cold-heat exchanger 5 entering the cold-heat exchanger 5.

As shown in fig. 5, as a preferred embodiment of the present invention, the ball collector 33 includes:

a ball collector case 331;

the ball collector inlet 334 is arranged on the ball collector shell 331 and is communicated with the rubber ball circulating pump 31 through a pipeline;

a ball collector outlet 333 which is arranged on the ball collector shell 331 and communicated with the ball injection pipe;

an exhaust port 336 provided in the ball collector case 331 and communicating with the exhaust valve 36;

a drain hole 337 provided in the ball collector case 331 and communicating with the drain valve 38;

the ball collecting basket 338 is used for collecting the cleaning rubber balls 1 pumped by the rubber ball circulating pump 31;

a switching valve 3310 for switching the operation state of the ball collector 33;

a ball collector driving assembly 332 for driving the switching valve 3310 to operate;

and a check valve 339 for preventing the cleaning rubber balls 1 collected by the ball collection basket 338 from flowing back to the rubber ball circulation pump 31.

Specifically, the ball collector 33 has the functions of collecting, replacing and placing balls, and is divided into two different types, namely C13 and C55, which can be selected according to the actual conditions of the project. The collector case 331 is made of St 37.0 steel and lined with rubber. Most of the metal parts inside the ball collector housing 331 are castings, and most of the non-metal parts are made of polyester materials. Ball collector 33 can be exhausted and drained through exhaust port 336 and drain port 337, respectively. The ball collector 33 can be filled or removed with a ball by opening the cover of the ball collector 33. To accomplish this, the inlet valve 34 and outlet valve 35 at the inlet 334 and outlet of the ball trap must be closed. The check valve 339 may prevent the backflow of the cleaning rubber ball 1 when the rubber ball circulation pump 31 is turned off. The switching valve 3310 is driven by the ball collector driving unit 332, and is switched such that the switching valve 3310 is opened, and the cleaning rubber ball 1 together with the cooling water enters the ball collector 33 and flows out from the ball collector outlet 333; the switch valve 3310 is closed and water flows out through the meshes of the ball collection basket 338 while the cleaning rubber balls 1 remain on the ball collection basket 338. Ball collector drive assembly 332 is regulated by a control mechanism.

As shown in fig. 6, as a preferred embodiment of the present invention, the differential pressure measuring mechanism 7 includes:

a high-pressure joint 72 communicating with the ball receiver mechanism 2;

a low pressure joint 73 communicating with the ball receiver mechanism 2;

a differential pressure transmitter 71 in communication with the high pressure fitting 72 and the low pressure fitting 73;

a flushing head 74 communicating with the differential pressure transmitter 71 through a pipe;

and a flushing valve 75 provided in a pipe connecting the flushing head 74 and the differential pressure transmitter 71.

Specifically, the differential pressure transmitter 71 can electronically process the differential pressure detected by the high pressure connector 72 and the low pressure connector 73 and convert the processed differential pressure into a signal capable of being sent. The high pressure joint 72 communicates with the differential pressure transmitter 71 through a high pressure side flexible pipe, and the low pressure joint 73 communicates with the differential pressure transmitter 71 through a low pressure side flexible pipe. The high-pressure side flexible pipe, the low-pressure side flexible pipe and the flushing valve 75 are communicated with the differential pressure transmitter 71 through the adapter, the sleeve nut isolation valve and the plug.

As a preferred embodiment of the present invention, the control mechanism includes:

a logic control unit, in which a control program is stored; the ball collecting device mechanism 2, the circulating mechanism 3 and the differential pressure measuring mechanism 7 are all electrically connected with the logic control unit;

Specifically, the control switch on the control panel has three cleaning mode options, namely MANUAL, AUTOMATIC LOCAL and AUTOMATIC REMOTE, and also has other function keys for further operating functions. All field cables are connected to the control mechanism according to the electrical file. When the MANUAL mode is selected, the driving components are controlled manually through function keys on a control panel, and an operation panel displays the actual running states of the driving components; when the AUTOMATIC LOCAL mode is selected, the driving assemblies are controlled by the control mechanism, the operation panel displays the actual running states of the driving assemblies, but all valves of the rubber ball cleaning device must be manually operated; the AUTOMATIC release mode is selected similarly to the AUTOMATIC LOCAL mode, but operation of the glue ball cleaning apparatus can only be activated or deactivated by the control room.

As a preferred embodiment of the present invention, a backwashing program is included in the control program.

Specifically, the differential pressure measuring mechanism 7 detects the differential pressure value at the ball receiver mechanism 2 in real time, and when the differential pressure value reaches a preset limit value of ball receiving/backwashing (backwashing program), the control mechanism starts ball receiving and screen plate backwashing; when the control mechanism breaks down and the limit value reaches the preset limit value, the ball collecting and the screen plate backwashing must be started manually. At the same time, the alarm assembly will issue an alarm signal.

As shown in fig. 1, as a preferred embodiment of the present invention, the rubber ball cleaning device further includes a secondary filter screen assembly 6, which is disposed at the water inlet end of the cold-heat exchanger 5, and is used for filtering impurities in the water entering the cold-heat exchanger 5.

Specifically, the secondary strainer assembly may filter impurities in the water entering the cold heat exchanger 5.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides a rubber ball belt cleaning device which characterized in that, rubber ball belt cleaning device includes:

a cold-heat exchanger with cleaning rubber balls inside;

2. The apparatus according to claim 1, wherein said ball collector mechanism comprises:

the ball outlet is arranged on the ball collector shell;

a ball net drive assembly for adjusting the tilt angle of the ball net;

and a baffle for generating a vortex inside the ball collector housing.

3. The apparatus for cleaning rubber balls according to claim 1, wherein the circulation mechanism comprises:

the ball inlet pipe is communicated with the ball collector mechanism;

the inlet valve is arranged on the ball inlet pipe;

the motor is used for driving the rubber ball circulating pump to operate;

the exhaust valve is arranged on the ball collector;

the drainage valve is arranged on the ball collector;

the outlet valve is arranged on the ball injection pipe;

4. The rubber ball cleaning device according to claim 3, wherein the ball collector comprises:

a ball collector housing;

5. The rubber ball cleaning device according to claim 1, wherein the differential pressure measuring mechanism comprises:

the high-pressure joint is communicated with the ball collector mechanism;

the low-pressure joint is communicated with the ball collector mechanism;

6. The rubber ball cleaning device according to claim 1, wherein the control mechanism comprises:

7. The rubber ball cleaning device according to claim 6, wherein a backwashing program is included in the control program.

8. The apparatus as claimed in claim 1, further comprising a secondary strainer assembly disposed at the water inlet end of the heat exchanger for filtering impurities in the water entering the heat exchanger.