CN216080570U - Cooling water pool circulating water supply device for zinc production - Google Patents

Abstract

The utility model discloses a cooling water pool circulating water supply device for zinc production, and relates to the technical field of industrial zinc production. The water circulation device comprises a cooling pool, wherein a circulation mechanism is arranged on one side of the cooling pool, the circulation mechanism comprises a water pump A and a heat exchange box, the heat exchange box is positioned right behind the water pump A, a water delivery mechanism comprises a filter box, a water pump B and a water storage tank, the filter box is positioned on one side behind the water pump B, a coarse filter screen and a fine filter screen are respectively arranged on two sides inside the filter box, and a ball float valve is arranged at the top of a water inlet pipe B. According to the utility model, by utilizing the filter box and the water storage tank, water passes through the coarse filter screen and the fine filter screen in sequence to filter impurities in the water, so that the pipeline is prevented from being blocked by the impurities, and the water temperature in the cooling tank is prevented from being influenced by the impurities.

Description

Cooling water pool circulating water supply device for zinc production

Technical Field

The utility model belongs to the technical field of industrial zinc production, and particularly relates to a cooling water pool circulating water supply device for zinc production.

Background

In modern life and production, the cell is indispensable, and in modern industry, zinc has a status of being unburnable for manufacturing the cell, and smelting of zinc is divided into two types: pyrometallurgical and hydrometallurgy, the one step indispensable to the smelting process of zinc is the cooling, cools off the zinc that high temperature was smelted out, then carries out subsequent operation to it again, often will use cooling water pond circulation water feeding device when cooling, reduces the energy consumption in the refrigerated, reduces the energy waste, but it still has following drawback in the in-service use:

1. when the existing circulating water delivery device of the cooling water pool is used, most of the circulating water delivery device of the cooling water pool is directly added into the cooling water pool through an external water source or recycled water, so that the situation that the pipeline is blocked by excessive impurities in water can occur, the water temperature in the cooling water pool is influenced by the excessive impurities, and the cooling effect is poor;

2. when the existing circulating water delivery device of the cooling water pool is used, the water delivery and water pumping amount at each time is inconsistent, so that the total water amount in the cooling water pool is continuously changed, the water temperature is continuously changed, the cooling effect is poor, and the product can be possibly influenced.

Therefore, the existing cooling water pool circulating water supply device for zinc production cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a circulating water delivery device of a cooling water pool for zinc production, which utilizes a filter box and a water storage tank, wherein a water pump B pumps water in the water storage tank out, and the water sequentially passes through a coarse filter screen in the filter box to filter out larger impurities in the water and then passes through a fine filter screen to filter out smaller substances in the water, so that the pipeline can be prevented from being blocked by the impurities in the water, the water temperature in the cooling pool is prevented from being influenced by the impurities, the pumped water and the delivered water are consistent through a ball float valve in the water storage tank, and the total water volume in the cooling pool is further kept unchanged, so that the water temperature in the cooling pool can be kept constant in the long-time cooling process, the cooling effect is prevented from being influenced by the continuous change of the water temperature in the cooling pool, and the influence of the water temperature change on products is prevented.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a cooling water pool circulating water supply device for zinc production, which comprises a cooling pool, wherein one side of the cooling pool is provided with a circulating mechanism, the circulating mechanism comprises a water pump A and a heat exchange box, the heat exchange box is positioned right behind the water pump A, the other side of the cooling pool is provided with a water supply mechanism, the water supply mechanism comprises a filter box, a water pump B and a water storage tank, the filter box is positioned on one side behind the water pump B, the water storage tank is positioned right in front of the water pump B, two sides inside the filter box are respectively provided with a coarse filter screen and a fine filter screen, a water inlet pipe B is arranged inside the water storage tank, the top of the water inlet pipe B is provided with a ball float valve, water is secondarily filtered through the coarse filter screen and the fine filter screen, impurities in the water are removed, and the consistency of water outlet and water inlet can be ensured through the ball float valve.

Further, one side outer wall top and the bottom of cooling tank are provided with drain pipe A and drain pipe B respectively, the opposite side outer wall top and the bottom of cooling tank are provided with flow pipe A and flow pipe B respectively, and the internally mounted of cooling tank has temperature sensor, and drain pipe A and flow pipe A are located the upper strata of cooling tank respectively, and drain pipe B and flow pipe B are located the lower floor of cooling tank respectively, and such setting can make the temperature of upper strata water and lower floor's water in the cooling tank stable even.

Further, water pump A's the end of intaking is connected with connecting pipe A and connecting pipe B respectively through three piecings, connecting pipe A's the other end passes through the coupling and is connected with drain pipe A, connecting pipe B's the other end passes through the coupling and is connected with drain pipe B, and three piecings and coupling all play the effect of pipe connection.

Further, water pump A's the delivery end passes through the coupling and is connected with the one end of connecting pipe C, the other end of connecting pipe C passes through the coupling and replaces the union coupling, the other end of replacement pipe runs through the rear end terminal surface and one side outer wall of heat transfer case in proper order and is connected with connecting pipe D through the coupling, connecting pipe D's the other end passes through the coupling and is connected with inlet tube B, and the replacement pipe is located the inside of heat transfer case, and hot water gets into the cold water emergence energy conversion in replacement pipe and the heat transfer case, reduces the temperature cycle and uses, reduces the water waste.

Furthermore, a water adding pipe is arranged at the top of the front end face of the water storage tank, a water adding valve is installed on the water adding pipe, a water outlet pipe B is arranged at the bottom of the rear end face of the water storage tank, a water outlet valve is installed on the water outlet pipe B, and water can be added into the water storage tank through the water adding pipe.

Further, the other end of outlet pipe B passes through the coupling and is connected with water pump B, water pump B's outlet end passes through the coupling and is connected with connecting pipe G, connecting pipe G's the other end passes through the coupling and is connected with inlet tube A, inlet tube A's the other end sets up in one side outer wall bottom of rose box, and water in the water storage tank is taken out to water pump B and enters into the rose box.

Furthermore, a water outlet pipe A is arranged at the bottom of the outer wall of the other side of the filter box, the other end of the water outlet pipe A is connected with a connecting pipe E and a connecting pipe F through three joints respectively, the other end of the connecting pipe E is connected with a water supply pipe A through a pipe joint, the other end of the connecting pipe F is connected with a water supply pipe B through a pipe joint, and filtered water enters the cooling tank through the water supply pipe A and the water supply pipe B respectively.

The utility model has the following beneficial effects:

1. according to the utility model, the filter tank is arranged, when a worker uses the circulating water delivery device, the water pump B is started, the water pump B operates to pump out water in the water storage tank through the water outlet pipe B and pumps the water into the filter tank through the connecting pipe G, the pumped water firstly filters out larger impurities in the water through the coarse filter screen in the filter tank and then filters out smaller substances in the water through the fine filter screen, so that the situation that the pipeline is blocked by the impurities in the water and the water temperature in the cooling pool is prevented from being influenced by the impurities is avoided, and the problems that when the existing circulating water delivery device of the cooling pool is used, most of the water is directly added into the cooling pool through an external water source or recycled water, the pipeline is blocked by the excessive impurities in the water, the water temperature in the cooling pool is influenced by the excessive impurities, and the cooling effect is poor are solved.

2. The utility model sets the water storage tank, when the staff uses, if the temperature sensor in the cooling tank detects that the water temperature reaches the preset water temperature, the water pump A and the water pump B are started, the water pump B pumps the water in the water storage tank into the cooling tank, simultaneously the water level in the water storage tank descends, at the moment, the floating ball on the floating ball valve above the water inlet pipe B descends along with the water level, the water inlet pipe B is opened, the water pumped by the water pump A through the water discharge pipe A and the water discharge pipe B enters the replacement pipe in the heat exchange tank for heat exchange, at the moment, the water in the replacement pipe enters the water storage tank as the water inlet pipe B is opened, then the floating ball rises along with the rising of the water level, and the floating ball valve is closed, thereby when pumping and delivering water to the cooling tank, the pumped water and the delivered water are consistent, further, the total water quantity in the cooling tank is not changed, therefore, the water temperature in the cooling tank can be kept constant in the long-time cooling process, avoid the temperature continuous change in the cooling pond to influence the cooling effect to and prevent that the temperature from changing and exert an influence to the product, solved current cooling pond circulation and sent water device when using, send water and the volume of drawing water inconsistent at every turn, consequently cause the water total amount continuous change in the cooling pond, thereby cause the temperature continuous change, lead to the cooling effect to worsen, and probably lead to the fact the problem of influence to the product.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced 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 that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a cross-sectional view of a cooling pool of the present invention;

FIG. 3 is a block diagram of the circulation mechanism of the present invention;

FIG. 4 is an internal structural view of the heat exchange box of the present invention;

FIG. 5 is a structural view of the water feed mechanism of the present invention;

FIG. 6 is a cross-sectional view of a filtration tank of the present invention;

FIG. 7 is a block diagram of the water storage tank of the present invention;

fig. 8 is a structural view of the water inlet pipe B of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a cooling pool; 101. a water drainage pipe A; 102. a water discharge pipe B; 103. a water supply pipe A; 104. a water supply pipe B; 2. a circulating mechanism; 201. a water pump A; 2011. a connecting pipe A; 2012. a connecting pipe B; 202. a trisection joint; 203. a pipe joint; 204. a heat exchange box; 2041. replacing the tube; 2042. a connecting pipe C; 2043. a connecting pipe D; 3. a water delivery mechanism; 301. a filter box; 3011. a coarse filter screen; 3012. a fine filter screen; 3013. a water inlet pipe A; 3014. a water outlet pipe A; 3015. a connecting pipe E; 3016. a connecting pipe F; 302. a water pump B; 3021. a connecting pipe G; 303. a water storage tank; 3031. a water feeding pipe; 3032. a water adding valve; 3033. a water outlet pipe B; 3034. a water outlet valve; 3035. a water inlet pipe B; 3036. a float valve.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-8, the utility model is a cooling water pool circulating water supply device for zinc production, comprising a cooling pool 1, a circulating mechanism 2 is arranged on one side of the cooling pool 1, the circulating mechanism 2 comprises a water pump a201 and a heat exchange box 204, the heat exchange box 204 is positioned right behind the water pump a201, a water supply mechanism 3 is arranged on the other side of the cooling pool 1, the water supply mechanism 3 comprises a filter box 301, a water pump B302 and a water storage tank 303, the filter box 301 is positioned on one side behind the water pump B302, the water storage tank 303 is positioned right ahead of the water pump B302, a coarse filter screen 3011 and a fine filter screen 3012 are respectively arranged on two sides inside the filter box 301, a water inlet pipe B3035 is arranged inside the water storage tank 303, a float valve 3036 is arranged on the top of the water inlet pipe B3035, water is secondarily filtered through the coarse filter screen 3011 and the fine filter screen 3012 to remove impurities in the water, the water outlet amount can be ensured to be consistent with the water inlet amount through the float valve 3036, the working principle of the float valve 3036 is that the float valve 3036 adjusts the liquid supply amount by controlling the liquid level, when the water surface rises, the float ball rises, the ball drives the connecting rod to rise, the connecting rod is connected with the valve at the other end, when the water surface rises to a certain position, the float ball is submerged by the water surface, the connecting rod supports the rubber piston pad to seal the water source, when the water level falls, the float also falls, and the connecting rod drives the piston pad to open;

the water pump B302 is started, the water pump B302 operates to pump out water in the water storage tank 303 through the water outlet pipe B3033 and pumps the water into the filter tank 301 through the connecting pipe G3021, the pumped water firstly filters out larger impurities in the water through the coarse filter screen 3011 in the filter tank 301 and then filters out smaller substances in the water through the fine filter screen 3012, so that the situation that the pipeline is blocked by the impurities in the water can be avoided, and the influence of the impurities on the water temperature in the cooling tank 1 can be prevented;

if the temperature sensor in the cooling pool 1 detects that the water temperature reaches the preset water temperature, the water pump A201 and the water pump B302 are started, the water pump B302 pumps the water in the water storage tank 303 into the cooling pool 1, meanwhile, the water level in the water storage tank 303 drops, at the moment, the floating ball on the ball float valve 3036 above the water inlet pipe B3035 drops along with the water level, the water inlet pipe B3035 is opened, the water pumped by the water pump A201 through the water discharge pipe A101 and the water discharge pipe B102 enters the replacement pipe 2041 in the heat exchange tank 204 for heat exchange, at the moment, the water in the replacement pipe 2041 enters the water storage tank 303 as the water inlet pipe B3035 is opened, then the floating ball rises along with the rising of the water level, the ball float valve 3036 is closed, therefore, when the water is pumped out and sent into the cooling pool 1, the total water quantity in the cooling pool 1 is consistent, and the total water quantity in the cooling pool 1 is unchanged, therefore, the water temperature in the cooling pool 1 can be kept constant during a long time, avoid the continuous change of temperature of water in the cooling bath 1 to influence the cooling effect to and prevent that the temperature of water change from producing the influence to the product.

As shown in fig. 1-2, the top and the bottom of the outer wall of one side of the cooling pool 1 are respectively provided with a drain pipe a101 and a drain pipe B102, the top and the bottom of the outer wall of the other side of the cooling pool 1 are respectively provided with a water supply pipe a103 and a water supply pipe B104, a temperature sensor is installed inside the cooling pool 1, the drain pipe a101 and the water supply pipe a103 are respectively located at the upper layer of the cooling pool 1, and the drain pipe B102 and the water supply pipe B104 are respectively located at the lower layer of the cooling pool 1, so that the temperatures of the water at the upper layer and the water at the lower layer in the cooling pool 1 can be stable and uniform.

As shown in fig. 1, 3, and 4, a water inlet end of a water pump a201 is connected to a connection pipe a2011 and a connection pipe B2012 respectively through a three-way joint 202, the other end of the connection pipe a2011 is connected to a drain pipe a101 through a pipe joint 203, the other end of the connection pipe B2012 is connected to a drain pipe B102 through a pipe joint 203, the three-way joint 202 and the pipe joint 203 both function as a pipe connection, a water outlet end of the water pump a201 is connected to one end of a connection pipe C2042 through the pipe joint 203, the other end of the connection pipe C2042 is connected to a replacement pipe 2041 through the pipe joint 203, the other end of the replacement pipe 2041 sequentially penetrates through a rear end face and one side outer wall of the heat exchange box 204 and is connected to a connection pipe D2043 through the pipe joint 203, the other end of the connection pipe D2043 is connected to a water inlet pipe B3035 through the pipe joint 203, the replacement pipe 2041 is located inside the heat exchange box 204, hot water enters the replacement pipe 2041 and is subjected to energy conversion with cold water in the heat exchange box 204, so as to reduce temperature recycling, reducing the waste of water resources.

As shown in fig. 1, 5 and 6, the other end of the water outlet pipe B3033 is connected with the water pump B302 through the pipe joint 203, the water outlet end of the water pump B302 is connected with the connecting pipe G3021 through the pipe joint 203, the other end of the connecting pipe G3021 is connected with the water inlet pipe a3013 through the pipe joint 203, the other end of the water inlet pipe a3013 is disposed at the bottom of the outer wall on one side of the filter tank 301, the water pump B302 pumps water in the water storage tank 303 and enters the filter tank 301, the water outlet pipe a3014 is disposed at the bottom of the outer wall on the other side of the filter tank 301, the other end of the water outlet pipe a3014 is respectively connected with the connecting pipe E3015 and the connecting pipe F3016 through the three-way joint 202, the other end of the connecting pipe E3015 is connected with the water supply pipe a103 through the pipe joint 203, the other end of the connecting pipe F3016 is connected with the water supply pipe B104 through the pipe joint 203, and the filtered water supply pipe a103 and B104 enter the interior of the cooling pool 1.

As shown in fig. 1, 5, and 7, a water feeding pipe 3031 is arranged at the top of the front end face of the water storage tank 303, a water feeding valve 3032 is installed on the water feeding pipe 3031, a water discharging pipe B3033 is arranged at the bottom of the rear end face of the water storage tank 303, a water discharging valve 3034 is installed on the water discharging pipe B3033, and water can be fed into the water storage tank 303 through the water feeding pipe 3031.

One specific application of this embodiment is: switching on a device power supply and starting the device; the temperature sensor in the cooling pool 1 senses the internal water temperature, if the water temperature reaches a preset temperature, the water pump A201 and the water pump B302 are started, the water pump A201 operates to pump water from the upper layer and the lower layer of the cooling pool 1 through the water discharge pipe A101 and the water discharge pipe B102 respectively and pump the water into the replacement pipe 2041 in the heat exchange tank 204 for cooling and heat exchange, at the moment, the water pump B302 operates to pump the water in the water storage tank 303 into the filter tank 301 through the water discharge pipe B3033, impurities in the water are filtered through the coarse filter screen 3011 and the fine filter screen 3012, then the water is sent into the upper layer and the lower layer of the cooling pool 1 through the water sending pipe A103 and the water sending pipe B104, at the time of water sending, the floating ball valve 3036 in the water storage tank 303 descends along with the descending of the water level, the floating ball valve 3036 is opened, the water in the replacement pipe 2041 flows into the water storage tank 303, at the moment, the floating ball rises along with the ascending of the water level, so that the water sent into the cooling pool 1 is consistent with the pumped water quantity, the total amount of water in the cooling pond 1 is kept constant.

The above are only preferred embodiments of the present invention, and the present invention is not limited thereto, and any modification, equivalent replacement, and improvement made to the technical solutions described in the above embodiments, and to some of the technical features thereof, are included in the scope of the present invention.

Claims (7)

1. The utility model provides a system zinc is with cooling water pond circulation water installation that send, includes cooling bath (1), its characterized in that: one side of cooling tank (1) is provided with circulation mechanism (2), circulation mechanism (2) include water pump A (201) and heat transfer case (204), heat transfer case (204) are located water pump A (201) dead astern, the opposite side of cooling tank (1) is provided with send water mechanism (3), send water mechanism (3) including rose box (301), water pump B (302) and storage water tank (303), rose box (301) are located water pump B (302) rear one side, storage water tank (303) are located water pump B (302) dead ahead, coarse filter screen (3011) and fine filter screen (3012) are installed respectively to the inside both sides of rose box (301), the internally mounted of storage water tank (303) has inlet tube B (3035), ball float valve (3036) is installed at the top of inlet tube B (3035).

2. The circulating water supply device of the cooling water pool for zinc production according to claim 1, wherein the top and the bottom of the outer wall of one side of the cooling pool (1) are respectively provided with a drain pipe A (101) and a drain pipe B (102), and the top and the bottom of the outer wall of the other side of the cooling pool (1) are respectively provided with a water supply pipe A (103) and a water supply pipe B (104).

3. The cooling water pool circulating water supply device for zinc making according to claim 1, wherein a water inlet end of the water pump A (201) is connected with a connecting pipe A (2011) and a connecting pipe B (2012) through a three-way joint (202), the other end of the connecting pipe A (2011) is connected with a drain pipe A (101) through a pipe joint (203), and the other end of the connecting pipe B (2012) is connected with a drain pipe B (102) through a pipe joint (203).

4. The cooling water pool circulating water supply device for zinc making according to claim 2, wherein the water outlet end of the water pump A (201) is connected with one end of a connecting pipe C (2042) through a pipe joint (203), the other end of the connecting pipe C (2042) is connected with a replacement pipe (2041) through the pipe joint (203), the other end of the replacement pipe (2041) sequentially penetrates through the rear end face and one side outer wall of the heat exchange box (204) and is connected with a connecting pipe D (2043) through the pipe joint (203), and the other end of the connecting pipe D (2043) is connected with a water inlet pipe B (3035) through the pipe joint (203).

5. The cooling water pool circulating water supply device for zinc making according to claim 1, characterized in that a water supply pipe (3031) is arranged at the top of the front end surface of the water storage tank (303), a water supply valve (3032) is installed on the water supply pipe (3031), a water outlet pipe B (3033) is arranged at the bottom of the rear end surface of the water storage tank (303), and a water outlet valve (3034) is installed on the water outlet pipe B (3033).

6. The cooling water pool circulating water supply device for zinc making as set forth in claim 5, characterized in that the other end of the outlet pipe B (3033) is connected with a water pump B (302) through a pipe joint (203), the outlet end of the water pump B (302) is connected with a connecting pipe G (3021) through the pipe joint (203), the other end of the connecting pipe G (3021) is connected with an inlet pipe A (3013) through the pipe joint (203), and the other end of the inlet pipe A (3013) is arranged at the bottom of the outer wall on one side of the filter tank (301).

7. The cooling water pool circulating water supply device for zinc making according to claim 6, wherein a water outlet pipe A (3014) is arranged at the bottom of the outer wall of the other side of the filter box (301), the other end of the water outlet pipe A (3014) is respectively connected with a connecting pipe E (3015) and a connecting pipe F (3016) through a three-way joint (202), the other end of the connecting pipe E (3015) is connected with a water supply pipe A (103) through a pipe joint (203), and the other end of the connecting pipe F (3016) is connected with a water supply pipe B (104) through a pipe joint (203).

Images