A secondary water supply device based on allowable residual chlorine

By installing a residual chlorine compensation component and an adaptive rotating spray component in the secondary water supply tank, the residual chlorine concentration can be automatically adjusted according to the temperature, solving the problem that the secondary water supply tank cannot adaptively increase or decrease chemical reagents, thus improving water quality and sterilization effect.

CN117868266BActive Publication Date: 2026-06-30FUZHOU ZHISHUI CRAFTSMAN DIGITAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
FUZHOU ZHISHUI CRAFTSMAN DIGITAL TECH CO LTD
Filing Date
2024-01-05
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing secondary water supply tanks cannot adaptively increase or decrease chemical reagents according to temperature, making it difficult to effectively control water quality issues.

Method used

A residual chlorine compensation component is installed on one side of the secondary water supply tank assembly. The residual chlorine compensation component monitors the water temperature in real time and automatically performs residual chlorine compensation based on the water temperature. Combined with the adaptive rotating spray assembly, it achieves full integration of residual chlorine with the water.

Benefits of technology

It enables the secondary water supply tank to adaptively add or remove chemical reagents, improving the qualification rate and sterilization effect of drinking water, and reducing maintenance costs and failure rate.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a secondary water supply device based on the allowable residual chlorine, comprising a residual chlorine compensation component, an adaptive rotating spray component, and a secondary water supply tank assembly. The residual chlorine compensation component is located on one side of the secondary water supply tank assembly, and the adaptive rotating spray component is located on the other side. By placing the residual chlorine compensation component on one side of the secondary water supply tank assembly, the invention enables real-time monitoring of the water temperature within the tank assembly and automatic residual chlorine compensation based on temperature variations. This achieves the technical effect of adaptively adding or removing chemical reagents in the secondary water supply tank, improving the pass rate of water quality within the tank. The adaptive rotating spray component ensures full integration of residual chlorine with the water, further enhancing the bactericidal effect of residual chlorine. The length change of the aforementioned compensation double-stroke memory spring is linearly related to the opening size of the compensation valve ball body, further improving the accuracy of residual chlorine compensation in the tank.
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Description

Technical Field

[0001] This invention belongs to the field of water supply equipment technology, specifically referring to a secondary water supply device based on the allowance of residual chlorine. Background Technology

[0002] Secondary water supply involves repressurizing urban public water supply to deliver it to higher floors. Traditional secondary water supply tanks (pools) and the currently widely used stainless steel square pressure membrane combination tanks are highly susceptible to the growth of plankton and microorganisms during storage. Surveys show that nearly a hundred species of algae grow and reproduce in high-rise water tanks, some of which produce toxins. The total bacterial count exceeds the standard in 100% of the tanks, and the coliform count exceeds the standard in 97.6% of the tanks. The color compliance rate is extremely low, and the total bacterial count increases with rising temperature. To ensure the quality of secondary water supply, in addition to strengthening management and improving the materials and structure of the tanks, it is also necessary to increase the sterilization efforts. Current measures involve adding chemical reagents trichloroisocyanuric acid and sodium dichloroisocyanurate to the secondary water supply tanks for secondary disinfection. However, commercially available secondary water supply tanks cannot adaptively adjust the amount of chemical reagents based on temperature. Therefore, there is an urgent need for a secondary water supply device based on the allowable residual chlorine level to solve these problems. Summary of the Invention

[0003] To address the above issues and overcome the shortcomings of existing technologies, this invention provides a secondary water supply device based on the allowance of residual chlorine. This effectively solves the problem that current secondary water supply tanks on the market cannot adaptively adjust the amount of chemical reagents based on temperature. By installing a residual chlorine compensation component on one side of the secondary water supply tank assembly, the device monitors the water temperature within the tank assembly in real time and automatically compensates for residual chlorine based on the temperature. This achieves the technical effect of adaptively adjusting the amount of chemical reagents in the secondary water supply tank, further improving the pass rate of drinking water in the tank. Furthermore, by setting an adaptive rotating spray component, residual chlorine is fully integrated with the water, thereby further enhancing the bactericidal effect of residual chlorine.

[0004] The technical solution adopted by this invention is as follows: This invention proposes a secondary water supply device based on permissible residual chlorine, including a residual chlorine compensation component, an adaptive rotating spray component, and a secondary water supply tank component. The residual chlorine compensation component is located on one side of the secondary water supply tank component, and the adaptive rotating spray component is located on the other side of the secondary water supply tank component. The residual chlorine compensation component includes a compensation temperature monitoring body, a compensation slide, a compensation double-stroke memory spring, a compensation slide plate, a compensation steel rope body, a compensation steel rope shell, a compensation drive lever, a compensation drive latch, a compensation drive rod body, a compensation drive wedge, a compensation driven wedge, a compensation valve ball push rod, a compensation valve ball body, a compensation valve ball sleeve, a sleeve shell, a valve ball push rod spring, a valve ball sleeve mounting bracket, a valve plug body, and a compensation valve ball push rod. The system includes a compensation control valve mounting bracket, a drive rod body external spring, a valve core sleeve, a compensation motor, a compensation residual chlorine tank body, a compensation inlet pipe, a compensation outlet pipe, a compensation spray connector, a spray connector sliding shaft, a compensation spray frame, a main residual chlorine inlet pipe, a compensation temperature monitoring shell, and a compensation monitoring inner cavity connecting pipe. Through a compensation double-stroke memory spring, the system can sense real-time changes in water temperature within the water supply tank body. The compensation double-stroke memory spring drives the compensation drive lever to rotate via a compensation slide and a compensation steel rope body, thereby realizing the opening and closing of the compensation valve ball body. Furthermore, the length change of the compensation double-stroke memory spring is linearly related to the opening size of the compensation valve ball body, thus achieving the function of adaptive linear addition and subtraction of chemical reagents in the secondary water supply tank, further improving the accuracy of residual chlorine compensation in the tank.

[0005] The compensation temperature monitoring body has an internal cavity, a compensation sliding column is located within the cavity, a compensation double-stroke memory spring is located outside the sliding column, a compensation sliding plate is slidably connected to one end of the sliding column, a compensation steel rope body is fixedly connected to the compensation sliding plate, a compensation steel rope outer shell is slidably connected to the compensation steel rope body, one end of the compensation drive lever is fixedly connected to the compensation steel rope body, the other end of the compensation drive lever is engaged in a compensation drive mounting plate, one end of the compensation drive rod body is fixedly connected to the compensation drive mounting plate, and the other end of the compensation drive rod body is fixedly connected to a compensation drive wedge. The moving wedge block and the compensating drive wedge block are slidably connected. One end of the compensating valve ball push rod is fixedly connected to the compensating driven wedge block, and the other end of the compensating valve ball push rod is fixedly connected to the compensating valve ball body. The compensating valve ball body is located inside the compensating valve ball sleeve, and the sleeve outer shell is located outside the compensating valve ball sleeve. The valve ball push rod spring is located outside the compensating valve ball push rod. The valve ball sleeve mounting bracket is fixedly connected to the compensating valve ball sleeve. The valve plug body is slidably connected to the compensating drive rod body. The compensating control valve mounting bracket is fixedly connected to the valve plug body. The drive rod body external spring is located outside the compensating drive rod body, and the elastic force of the drive rod body external spring is much greater than that of the two valve ball push rod springs. The elasticity of the valve core sleeve ensures that the residual chlorine compensation function remains dormant in low-temperature environments, preventing water quality deterioration due to chemical reagent leakage and thus improving the reliability of the device. The valve core sleeve is threadedly connected to the valve plug body. The compensation motor is connected to the residual chlorine compensation tank body via a liquid guide pipe. One end of the compensation inlet pipe is fixedly connected to the residual chlorine compensation tank body, and the other end is located inside the sleeve housing. One end of the compensation outlet pipe is fixedly connected to the sleeve housing, and the other end is snapped onto the compensation spray connector. The spray connector slide shaft is fixedly connected to the compensation spray connector. The compensation spray frame... The main residual chlorine inlet pipe is fixedly connected to the spray connector shaft, with one end snapped onto the compensation spray connector head and the other end fixedly connected to the compensation residual chlorine tank body. The compensation temperature monitoring shell is fixedly connected to the compensation temperature monitoring body, and the compensation monitoring inner cavity connecting pipe passes through one side of the compensation temperature monitoring body. By setting a residual chlorine compensation component on one side of the secondary water supply tank assembly, the residual chlorine compensation component monitors the water temperature in the secondary water supply tank assembly in real time and automatically performs residual chlorine compensation according to the water temperature. This achieves the technical effect of adaptively increasing or decreasing chemical reagents in the secondary water supply tank, further improving the qualification rate of drinking water in the tank.

[0006] Further, the adaptive rotary spraying assembly includes an adaptive rotary temperature monitoring body, an adaptive rotary slide column, an adaptive rotary double-stroke memory spring, an adaptive rotary slide plate, an adaptive rotary steel rope body, an adaptive rotary steel rope shell, an adaptive male contact, an upper section of an adaptive rotary motor conductor, an adaptive female contact, a lower section of an adaptive rotary motor conductor, an adaptive contact mounting bracket, an adaptive contact return spring, an adaptive rotary motor body, a rotary motor drive gear, an adaptive rotary monitoring inner cavity connecting pipe, an adaptive temperature monitoring shell, and a steel rope shell lever. The adaptive rotary temperature monitoring body has an internal adaptive rotary temperature monitoring cavity. The adaptive rotary slide column is located within the adaptive rotary temperature monitoring cavity. The adaptive rotary double-stroke memory spring is located outside the adaptive rotary slide column. The adaptive rotary slide plate is slidably connected to one end of the adaptive rotary slide column. The adaptive rotary steel rope body is fixedly connected to the adaptive rotary slide plate. The adaptive rotary steel rope shell is located outside the adaptive rotary steel rope body. The male contact is fixedly connected to the adaptive rotating steel rope body via a steel rope housing lever. The upper section of the adaptive rotating motor conductor is fixedly connected to the adaptive male contact. The adaptive female contact is located adjacent to the adaptive male contact. The lower section of the adaptive rotating motor conductor is fixedly connected to the adaptive female contact. Both the adaptive male and female contacts are located within the adaptive contact mounting bracket. One end of the adaptive contact return spring is fixedly connected to the steel rope housing lever, and the other end is fixedly connected to the outside of the adaptive contact mounting bracket. The conductor outside the adaptive rotating motor body is fixedly connected to the lower section of the adaptive rotating motor conductor. The rotating motor drive gear is fixedly connected to the output end of the adaptive rotating motor body. The adaptive rotating monitoring inner cavity connecting pipe penetrates the adaptive rotating temperature monitoring body. The adaptive temperature monitoring housing is fixedly connected to the adaptive rotating temperature monitoring body. By setting the adaptive rotating spray assembly, the residual chlorine is fully integrated with the water, thereby further improving the bactericidal effect of the residual chlorine.

[0007] Furthermore, the secondary water supply tank assembly includes a water supply tank body, a water supply tank cover, and a main water supply pipe. The water supply tank body is fixedly connected to the water supply tank cover, and the main water supply pipe is fixedly connected to the water supply tank body via a flange. A rotary motor mounting slot is provided on the upper part of the water supply tank cover, and a connecting head sliding shaft through hole is provided in the middle of the water supply tank cover. Rotary monitoring body mounting slots and compensation monitoring body mounting slots are respectively provided on both sides of the water supply tank body.

[0008] Furthermore, the compensation temperature monitoring body is located in the compensation monitoring body mounting slot, the compensation motor is fixedly connected to the water supply tank body through the mounting bracket, the spray connector slide shaft is rotatably connected to the connector slide shaft through hole, the compensation monitoring inner cavity connecting pipe passes through the water supply tank body, and the compensation control valve mounting bracket is fixedly connected to the water supply tank body.

[0009] Furthermore, the adaptive rotary motor body is fixedly connected to the rotary motor mounting slot, the rotary motor drive gear meshes with the teeth on the outside of the compensating spray connector, the adaptive rotary temperature monitoring body is located in the rotary monitoring body mounting slot, the adaptive rotary monitoring inner cavity connecting pipe passes through the water supply tank body, and the adaptive contact mounting bracket is fixedly connected to the side of the water supply tank body. The opening or closing function of the adaptive rotary motor body is realized by the length change of the adaptive rotary double-stroke memory spring. The structure is simple and the failure rate is low.

[0010] Furthermore, one end of the compensating double-stroke memory spring is fixedly connected to the compensating slide plate, and the other end of the compensating double-stroke memory spring is fixedly connected to the inside of the compensating temperature monitoring body. One end of the compensating steel rope shell is fixedly connected to the compensating temperature monitoring body, and the other end of the compensating steel rope shell is fixedly connected to the compensating control valve mounting bracket. The middle part of the compensating drive lever is hinged to the upper part of the compensating control valve mounting bracket via a pivot. The compensating drive lever body penetrates through the compensating control valve mounting bracket. One end of the external spring of the drive lever body is fixedly connected to the compensating control valve mounting bracket. The other end is located on the protrusion at the lower part of the compensation drive rod body. The compensation valve ball push rod passes through the valve ball sleeve mounting bracket. One end of the valve ball push rod spring is fixedly connected to the valve ball sleeve mounting bracket, and the other end of the valve ball push rod spring is fixedly connected to the compensation driven wedge. Both sides of the valve core sleeve are fixedly connected to the sleeve shell. The compensation spray frame is installed under the water supply tank cover. The compensation temperature monitoring body and the adaptive rotary temperature monitoring body are respectively installed outside the water supply tank body. When the compensation double-stroke memory spring and the adaptive rotary double-stroke memory spring fail due to age, the above configuration facilitates maintenance and reduces maintenance costs.

[0011] Furthermore, one end of the adaptive rotary two-way memory spring is fixedly connected to the adaptive rotary slider, the other end of the adaptive rotary two-way memory spring is fixedly connected to the inside of the adaptive rotary temperature monitoring body, one end of the adaptive rotary steel rope shell is fixedly connected to the adaptive rotary temperature monitoring body, and the other end of the adaptive rotary steel rope shell is fixedly connected to the outside of the adaptive contact mounting bracket.

[0012] Furthermore, both sides of the compensation drive wedge are provided with compensation driven wedges. Two compensation valve ball push rods, two compensation valve ball bodies, two compensation valve ball sleeves, two sleeve housings, two valve ball push rod springs, and two valve ball sleeve mounting brackets are provided. The compensation drive rod body is arranged perpendicularly to the compensation drive wedge, the compensation valve ball push rod is arranged perpendicularly to the compensation driven wedge, and the compensation valve ball push rod is arranged perpendicularly to the compensation valve ball body. One side of the steel rope housing push block is fixedly connected to the adaptive contact mounting bracket via an adaptive contact return spring, thereby effectively preventing the adaptive male contact from failing to return to its original position and thus effectively avoiding the burning failure of the adaptive male and female contacts.

[0013] Furthermore, both the compensation drive wedge and the compensation driven wedge are located inside the valve core sleeve, and both compensation valve ball bodies are located between the compensation valve ball sleeve and the valve ball sleeve mounting bracket.

[0014] The beneficial effects achieved by the present invention using the above structure are as follows:

[0015] (1) In order to solve the problem that the secondary water supply tank can adaptively increase or decrease chemical reagents according to the temperature, the present invention sets a residual chlorine compensation component on one side of the secondary water supply tank assembly. The residual chlorine compensation component monitors the water temperature in the secondary water supply tank assembly in real time and automatically performs residual chlorine compensation according to the water temperature, thereby realizing the technical effect of adaptively increasing or decreasing chemical reagents in the secondary water supply tank and further improving the qualification rate of drinking water in the tank.

[0016] (2) In this invention, the compensation monitoring inner cavity connecting pipe is connected to the water supply tank body. The water temperature change in the water supply tank body can be sensed in real time through the compensation double-stroke memory spring. The compensation double-stroke memory spring drives the compensation drive lever to rotate through the compensation slide and the compensation steel rope body, thereby realizing the opening and closing of the compensation valve ball body. The length change of the compensation double-stroke memory spring is linearly related to the opening size of the compensation valve ball body, thereby realizing the function of adaptive linear increase and decrease of chemical reagents in the secondary water supply tank, and further improving the accuracy of residual chlorine compensation in the tank.

[0017] (3) In this invention, the elastic force of the outer spring of the drive rod body is much greater than the elastic force of the two valve ball push rod springs, thereby ensuring that the residual chlorine compensation function of the device is in a dormant state under low temperature environment, preventing the water quality from deteriorating due to chemical reagent leakage, thereby improving the reliability of the device.

[0018] (4) In order to fully utilize the effect of residual chlorine compensation, the present invention achieves full fusion of residual chlorine and water by setting an adaptive rotating spray component, thereby further improving the bactericidal effect of residual chlorine;

[0019] (5) This invention uses an adaptive rotary two-way memory spring to sense the water temperature change of the water supply tank in real time, and realizes the opening or closing function of the adaptive rotary motor body by the length change of the adaptive rotary two-way memory spring. The structure is simple and the failure rate is low.

[0020] (6) In this invention, the compensating temperature monitoring body and the adaptive rotating temperature monitoring body are respectively located outside the water supply tank body. When the compensating two-way memory spring and the adaptive rotating two-way memory spring fail due to age, the above-mentioned arrangement facilitates maintenance and reduces maintenance costs.

[0021] (7) In this invention, one side of the steel rope outer shell block is fixedly connected to the adaptive contact mounting bracket through the adaptive contact reset spring, thereby effectively preventing the adaptive male contact from failing to return to its original position, and thus effectively avoiding the occurrence of burn-out faults of the adaptive male contact and the adaptive female contact. Attached Figure Description

[0022] Figure 1 This is a three-dimensional structural diagram of a secondary water supply device based on the allowable residual chlorine proposed in this invention. Figure 1 ;

[0023] Figure 2 This is a three-dimensional structural diagram of a secondary water supply device based on the allowable residual chlorine proposed in this invention. Figure 2 ;

[0024] Figure 3 This is a three-dimensional exploded structural diagram of a secondary water supply device based on the allowance of residual chlorine proposed in this invention.

[0025] Figure 4 This is a three-dimensional structural schematic diagram of a residual chlorine compensation component of a secondary water supply device based on the allowable residual chlorine proposed in this invention;

[0026] Figure 5 This is a schematic diagram of the exploded three-dimensional structure of a residual chlorine compensation component of a secondary water supply device based on the allowable residual chlorine proposed in this invention.

[0027] Figure 6 This is a schematic diagram of the exploded three-dimensional structure of a residual chlorine compensation component of a secondary water supply device based on the allowable residual chlorine proposed in this invention.

[0028] Figure 7 for Figure 5 A magnified view of a section at point A in the middle;

[0029] Figure 8 for Figure 5 A magnified view of a section at point B in the middle;

[0030] Figure 9This is an exploded three-dimensional structural diagram of an adaptive rotating spray assembly for a secondary water supply device that allows residual chlorine, as proposed in this invention. Figure 1 ;

[0031] Figure 10 This is an exploded three-dimensional structural diagram of an adaptive rotating spray assembly for a secondary water supply device that allows residual chlorine, as proposed in this invention. Figure 2 ;

[0032] Figure 11 for Figure 9 A magnified view of a section at point C;

[0033] Figure 12 for Figure 10 A magnified view of a section at point D;

[0034] Figure 13 This is a three-dimensional structural diagram of the secondary water supply tank assembly of a secondary water supply device based on the principle of allowing residual chlorine, as proposed in this invention. Figure 1 ;

[0035] Figure 14 This is a three-dimensional structural diagram of the secondary water supply tank assembly of a secondary water supply device based on the principle of allowing residual chlorine, as proposed in this invention. Figure 2 .

[0036] Among them, 1. Residual chlorine compensation component; 100. Compensation temperature monitoring body; 101. Compensation temperature monitoring inner cavity; 102. Compensation slide column; 103. Compensation double-stroke memory spring; 104. Compensation slide plate; 105. Compensation steel rope body; 106. Compensation steel rope outer shell; 107. Compensation drive lever; 108. Compensation drive chuck; 109. Compensation drive rod body; 110. Compensation drive wedge; 111. Compensation driven wedge; 112. Compensation valve ball push rod; 113. Compensation valve ball body; 114. Compensation valve ball sleeve; 1 15. Sleeve housing; 116. Valve ball push rod spring; 117. Valve ball sleeve mounting bracket; 118. Valve plug body; 119. Compensating control valve mounting bracket; 120. External spring of drive rod body; 121. Valve core sleeve; 122. Compensating motor; 123. Compensating residual chlorine tank body; 124. Compensating inlet pipe; 125. Compensating outlet pipe; 126. Compensating spray connector; 127. Spray connector slide shaft; 128. Compensating spray frame; 129. Main residual chlorine inlet pipe; 130. Compensating temperature monitoring housing; 131. Supplement 1. Compensation monitoring inner cavity connecting pipe; 2. Adaptive rotating spray assembly; 200. Adaptive rotating temperature monitoring body; 201. Adaptive rotating temperature monitoring inner cavity; 202. Adaptive rotating slide column; 203. Adaptive rotating two-way memory spring; 204. Adaptive rotating slide plate; 205. Adaptive rotating steel rope body; 206. Adaptive rotating steel rope outer shell; 207. Adaptive male contact; 208. Upper section of adaptive rotating motor wire; 209. Adaptive female contact; 210. Lower section of adaptive rotating motor wire; 211. Adaptive... 212. Adaptive contact mounting bracket; 213. Adaptive rotary motor body; 214. Rotary motor drive gear; 215. Adaptive rotary monitoring inner cavity connecting pipe; 216. Adaptive temperature monitoring housing; 217. Steel rope housing lever; 3. Secondary water supply tank assembly; 300. Water supply tank body; 301. Water supply tank cover; 302. Main water supply pipe; 303. Rotary motor mounting slot; 304. Connector sliding shaft through hole; 305. Rotary monitoring body mounting slot; 306. Compensation monitoring body mounting slot.

[0037] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used together with the embodiments of the invention to explain the invention and do not constitute a limitation thereof. Detailed Implementation

[0038] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative effort are within the scope of protection of the present invention.

[0039] In the description of this invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.

[0040] like Figures 1-14 As shown, this invention proposes a secondary water supply device based on allowing residual chlorine, including a residual chlorine compensation component 1, an adaptive rotating spray component 2, and a secondary water supply tank component 3. By setting the adaptive rotating spray component 2, the residual chlorine is fully integrated with the water, thereby further improving the sterilization effect of the residual chlorine. The residual chlorine compensation component 1 is located on one side of the secondary water supply tank component 3, and the adaptive rotating spray component 2 is located on the other side of the secondary water supply tank component 3. The residual chlorine compensation component 1 includes a compensation temperature monitoring body 100, a compensation sliding column 102, a compensation dual-stroke memory spring 103, a compensation sliding plate 104, a compensation steel rope body 105, a compensation steel rope outer shell 106, a compensation drive lever 107, a compensation drive locking plate 108, a compensation drive rod body 109, a compensation drive wedge 110, a compensation driven wedge 111, a compensation valve ball push rod 112, a compensation valve ball body 113, a compensation valve ball sleeve 114, a sleeve outer shell 115, and a valve ball push rod. The components include a rod spring 116, a valve ball sleeve mounting bracket 117, a valve plug body 118, a compensation control valve mounting bracket 119, a drive rod body external spring 120, a valve core sleeve 121, a compensation motor 122, a compensation residual chlorine tank body 123, a compensation inlet pipe 124, a compensation outlet pipe 125, a compensation spray connector 126, a spray connector sliding shaft 127, a compensation spray frame 128, a main residual chlorine inlet pipe 129, a compensation temperature monitoring shell 130, and a compensation monitoring inner cavity connecting pipe 131. To address the issue of the secondary water supply tank adaptively increasing or decreasing chemical reagents based on temperature, this invention sets a residual chlorine compensation component 1 on one side of the secondary water supply tank assembly 3. The residual chlorine compensation component 1 monitors the water temperature inside the secondary water supply tank assembly 3 in real time and automatically performs residual chlorine compensation based on the water temperature, thereby achieving the technical effect of adaptively increasing or decreasing chemical reagents in the secondary water supply tank and further improving the qualification rate of drinking water in the tank.

[0041] The compensation temperature monitoring body 100 has an internal compensation temperature monitoring cavity 101. A compensation slide 102 is located inside the compensation temperature monitoring cavity 101. A compensation double-stroke memory spring 103 is located outside the compensation slide 102. A compensation slide plate 104 is slidably connected to one end of the compensation slide 102. A compensation steel rope body 105 is fixedly connected to the compensation slide plate 104. A compensation steel rope outer shell 106 is slidably connected to the compensation steel rope body 105. One end of the compensation drive lever 107 is fixedly connected to the compensation steel rope body 105, and the other end of the compensation drive lever 107 is engaged in the compensation drive mounting plate 108. One end of the compensation drive rod body 109 is fixedly connected to the compensation drive mounting plate 108, and the other end of the compensation drive rod body 109 is fixedly connected to the compensation drive... Wedge 110, compensating driven wedge 111 and compensating driving wedge 110 are slidably connected, one end of compensating valve ball push rod 112 is fixedly connected to compensating driven wedge 111, the other end of compensating valve ball push rod 112 is fixedly connected to compensating valve ball body 113, compensating valve ball body 113 is located inside compensating valve ball sleeve 114, sleeve outer shell 115 is located outside compensating valve ball sleeve 114, valve ball push rod spring 116 is located outside compensating valve ball push rod 112, valve ball sleeve mounting bracket 117 is fixedly connected to compensating valve ball sleeve 114, valve plug body 118 is slidably connected to compensating driving rod body 109, compensating control valve mounting bracket 119 is fixedly connected to valve plug body 118, and driving rod body external spring 120 is located outside compensating driving rod body 109. The valve core sleeve 121 is threadedly connected to the valve plug body 118. The compensation motor 122 is connected to the compensation residual chlorine tank body 123 via a liquid guide pipe. One end of the compensation inlet pipe 124 is fixedly connected to the compensation residual chlorine tank body 123, and the other end of the compensation inlet pipe 124 is located inside the sleeve housing 115. One end of the compensation outlet pipe 125 is fixedly connected to the sleeve housing 115, and the other end of the compensation outlet pipe 125 is snapped onto the compensation spray connector 126. The spray connector slide shaft 127 is fixedly connected to the compensation spray connector 126. The compensation spray frame 128 is fixedly connected to the spray connector slide shaft 127. One end of the main residual chlorine inlet pipe 129 is snapped onto the compensation spray connector 126, and the other end of the main residual chlorine inlet pipe 129 is fixedly connected to the compensation residual chlorine tank body. The compensation temperature monitoring housing 130 is fixedly connected to the compensation temperature monitoring body 100. The compensation monitoring inner cavity connecting pipe 131 passes through one side of the compensation temperature monitoring body 100 and is connected to the water supply tank body 300. The compensation double-stroke memory spring 103 can sense the water temperature change in the water supply tank body 300 in real time. The compensation double-stroke memory spring 103 drives the compensation drive lever 107 to rotate through the compensation slide 104 and the compensation steel rope body 105, thereby realizing the opening and closing of the compensation valve ball body 113. The length change of the compensation double-stroke memory spring 103 is linearly related to the opening size of the compensation valve ball body 113, thus realizing the function of adaptive linear addition and subtraction of chemical reagents in the secondary water supply tank.This further improves the accuracy of residual chlorine compensation in the tank water.

[0042] The adaptive rotary spraying assembly 2 includes an adaptive rotary temperature monitoring body 200, an adaptive rotary slide column 202, an adaptive rotary double-stroke memory spring 203, an adaptive rotary slide plate 204, an adaptive rotary steel rope body 205, an adaptive rotary steel rope housing 206, an adaptive male contact 207, an upper section of an adaptive rotary motor conductor 208, an adaptive female contact 209, a lower section of an adaptive rotary motor conductor 210, an adaptive contact mounting bracket 211, an adaptive contact return spring 212, an adaptive rotary motor body 213, and a rotary motor drive gear 2. 14. An adaptive rotation monitoring inner cavity connecting pipe 215, an adaptive temperature monitoring outer shell 216, and a steel rope outer shell lever 217. An adaptive rotation temperature monitoring inner cavity 201 is formed inside the adaptive rotation temperature monitoring body 200. An adaptive rotation slide column 202 is located inside the adaptive rotation temperature monitoring inner cavity 201. An adaptive rotation double-stroke memory spring 203 is located outside the adaptive rotation slide column 202. An adaptive rotation slide plate 204 is slidably connected to one end of the adaptive rotation slide column 202. The adaptive rotation steel rope body 205 is fixedly connected to the adaptive rotation slide plate 204. An adaptive rotating steel rope housing 206 is disposed outside the adaptive rotating steel rope body 205. An adaptive male contact 207 is fixedly connected to the adaptive rotating steel rope body 205 via a steel rope housing lever 217. An upper section 208 of the adaptive rotating motor conductor is fixedly connected to the adaptive male contact 207. An adaptive female contact 209 is disposed adjacent to the adaptive male contact 207. A lower section 210 of the adaptive rotating motor conductor is fixedly connected to the adaptive female contact 209. Both the adaptive male contact 207 and the adaptive female contact 209 are disposed within the adaptive contact mounting bracket 211. One end of the reset spring 212 is fixedly connected to the steel rope housing lever 217, and the other end of the adaptive contact reset spring 212 is fixedly connected to the outside of the adaptive contact mounting bracket 211. The wire outside the adaptive rotary motor body 213 is fixedly connected to the lower section 210 of the adaptive rotary motor wire. The rotary motor drive gear 214 is fixedly connected to the output end of the adaptive rotary motor body 213. The adaptive rotary monitoring inner cavity connecting pipe 215 passes through the adaptive rotary temperature monitoring body 200. The adaptive temperature monitoring housing 216 is fixedly connected to the adaptive rotary temperature monitoring body 200.

[0043] In addition, the secondary water supply tank assembly 3 includes a water supply tank body 300, a water supply tank cover 301, and a main water supply pipe 302. The water supply tank body 300 is fixedly connected to the water supply tank cover 301, and the main water supply pipe 302 is fixedly connected to the water supply tank body 300 through a flange. A rotary motor mounting groove 303 is provided on the upper part of the water supply tank cover 301, and a connector sliding shaft through hole 304 is provided through the middle of the water supply tank cover 301. A rotary monitoring body mounting groove 305 and a compensation monitoring body mounting groove 306 are respectively provided on both sides of the water supply tank body 300.

[0044] In this embodiment, the compensation temperature monitoring body 100 is disposed in the compensation monitoring body mounting groove 306, the compensation motor 122 is fixedly connected to the water supply tank body 300 through the mounting bracket, the spray connector sliding shaft 127 is rotatably connected to the connector sliding shaft through hole 304, the compensation monitoring inner cavity connecting pipe 131 penetrates the water supply tank body 300, the compensation control valve mounting bracket 119 is fixedly connected to the water supply tank body 300, the adaptive rotary motor body 213 is fixedly connected to the rotary motor mounting groove 303, the rotary motor drive gear 214 meshes with the teeth on the outside of the compensation spray connector 126, the adaptive rotary temperature monitoring body 200 is disposed in the rotary monitoring body mounting groove 305, the adaptive rotary monitoring inner cavity connecting pipe 215 penetrates the water supply tank body 300, and the adaptive contact mounting bracket 211 is fixedly connected to the side of the water supply tank body 300.

[0045] In this embodiment, one end of the compensation double-stroke memory spring 103 is fixedly connected to the compensation slider 104, and the other end of the compensation double-stroke memory spring 103 is fixedly connected to the inner side of the compensation temperature monitoring body 100. One end of the compensation steel rope shell 106 is fixedly connected to the compensation temperature monitoring body 100, and the other end of the compensation steel rope shell 106 is fixedly connected to the compensation control valve mounting bracket 119. The middle part of the compensation drive lever 107 is hinged to the upper part of the compensation control valve mounting bracket 119 through a pivot. The compensation drive lever body 109 passes through the compensation... The control valve mounting bracket 119 has one end of the external spring 120 of the drive rod body fixedly connected to the compensation control valve mounting bracket 119, and the other end of the external spring 120 of the drive rod body is located on the boss at the lower part of the compensation drive rod body 109. The compensation valve ball push rod 112 passes through the valve ball sleeve mounting bracket 117. One end of the valve ball push rod spring 116 is fixedly connected to the valve ball sleeve mounting bracket 117, and the other end of the valve ball push rod spring 116 is fixedly connected to the compensation driven wedge 111. Both sides of the valve core sleeve 121 are fixedly connected to the sleeve outer shell 115. The compensating spray frame 128 is located under the water supply tank cover 301. One end of the adaptive rotary double-pass memory spring 203 is fixedly connected to the adaptive rotary slide 204, and the other end of the adaptive rotary double-pass memory spring 203 is fixedly connected to the inside of the adaptive rotary temperature monitoring body 200. The adaptive rotary double-pass memory spring 203 senses the water temperature change of the water supply tank body 300 in real time, and realizes the opening or closing function of the adaptive rotary motor body 213 by the length change of the adaptive rotary double-pass memory spring 203. The structure is simple and the failure rate is low. One end of the adaptive rotary steel rope shell 206 is fixedly connected to the adaptive rotary temperature monitoring body 200, and the other end of the adaptive rotary steel rope shell 206 is fixedly connected to the outside of the adaptive contact mounting bracket 211. The elastic force of the outer spring 120 of the drive rod body is much greater than the elastic force of the two valve ball push rod springs 116, thus ensuring that the residual chlorine compensation function of the device is in a dormant state in the low temperature environment, preventing the water quality from deteriorating due to chemical reagent leakage, thereby improving the reliability of the device.

[0046] In this embodiment, compensation driven wedges 111 are provided on both sides of the compensation drive wedge 110. Two compensation valve ball push rods 112, two compensation valve ball bodies 113, two compensation valve ball sleeves 114, two sleeve shells 115, two valve ball push rod springs 116, and two valve ball sleeve mounting brackets 117 are provided. The compensation drive rod body 109 is arranged perpendicularly to the compensation drive wedge 110, the compensation valve ball push rod 112 is arranged perpendicularly to the compensation driven wedges 111, and the compensation valve ball push rod 112 is arranged perpendicularly to the compensation valve ball body 113. The compensation drive wedge 110 and the compensation driven wedges 111 are both located inside the valve core sleeve 121, and the two compensation valve ball bodies 113 are both located between the compensation valve ball sleeve 114 and the valve ball sleeve mounting bracket 117.

[0047] In actual use, add an appropriate amount of chemical reagent into the compensation residual chlorine tank body 123, and the drinking water from the urban water supply system is input into the water supply tank body 300.

[0048] When the room temperature is high, the water temperature in the water supply tank 300 rises, and this temperature is transmitted to the water in the compensation temperature monitoring chamber 101 through the compensation monitoring inner cavity connecting pipe 131. The compensation double-stroke memory spring 103 on the compensation slide column 102 will stretch proportionally with the temperature, and then the compensation steel rope body 105 will move the compensation drive lever 107 upward to move the compensation drive platform 108. The compensation drive platform 108 will then pull the compensation drive wedge 110 along the compensation driven wedge 111 through the compensation drive rod body 109, overcoming the elastic force of the external spring 120 of the drive rod body. The valve ball push rod spring 116 pushes the compensation driven wedge 111, thereby driving the compensation valve ball push rod 112 to slide closer to the compensation drive wedge 110. In turn, the compensation valve ball push rod 112 pulls the compensation valve ball body 113 away from the compensation valve ball sleeve 114, thus reducing the temperature. The reagent flows into the compensation outlet pipe 125 through the compensation valve ball sleeve 114, thus realizing the opening efficiency of residual chlorine compensation. When the water temperature in the water supply tank 300 is too high, the adaptive rotating double-stroke memory spring 203 pulls the steel rope outer shell block 217 along one side of the adaptive contact mounting bracket 211 through the adaptive rotating steel rope body 205, thereby making the adaptive male contact 207 contact with the adaptive female contact 209. The upper section 208 of the adaptive rotating motor wire will be connected with the lower section 210 of the adaptive rotating motor wire, thus realizing the adaptive rotation effect of the adaptive rotating motor body 213. Then, the rotating motor drives the gear 214 to drive the compensation spray frame 128 to rotate through the teeth outside the compensation spray connector 126, so that the residual chlorine is fully mixed with the water in the secondary water supply tank, effectively improving the water quality in the tank.

[0049] When the room temperature is low, the water temperature in the water supply tank 300 will be low, and the compensation double-stroke memory spring 103 will be in a contracted state. The external spring 120 of the drive rod body will push the compensation drive wedge 110 to slide along the compensation driven wedge 111 through the compensation drive rod body 109. Then, the compensation driven wedge 111 will push the compensation valve ball body 113 to engage with the compensation valve ball sleeve 114 through the compensation valve ball push rod 112, thereby realizing the residual chlorine compensation closing function. In addition, due to the decrease in water temperature in the adaptive rotating temperature monitoring cavity 201, the adaptive rotating double-stroke memory spring 203 will also be in a contracted state. The steel rope outer shell push block 217 will slide back along one side of the adaptive contact mounting bracket 211 under the elastic force of the adaptive contact reset spring 212. The adaptive male contact 207 will separate from the adaptive female contact 209, thereby realizing the adaptive closing function of the adaptive rotating motor body 213.

[0050] The above is the overall workflow of this invention. Simply repeat this process the next time you use it.

[0051] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0052] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

[0053] The present invention and its embodiments have been described above. This description is not restrictive, and the accompanying drawings are only one embodiment of the present invention; the actual structure is not limited thereto. In conclusion, if those skilled in the art are inspired by this description and design similar structures and embodiments without departing from the spirit of the invention, such designs should fall within the protection scope of the present invention.

Claims

1. A secondary water supply device based on permissible residual chlorine, characterized in that: The system includes a residual chlorine compensation component, an adaptive rotary spray component, and a secondary water supply tank component. The residual chlorine compensation component is located on one side of the secondary water supply tank component, and the adaptive rotary spray component is located on the other side. The residual chlorine compensation component includes a compensation temperature monitoring body, which has an internal compensation temperature monitoring cavity. A compensation slide is located inside the compensation temperature monitoring cavity, a compensation double-stroke memory spring is located outside the compensation slide, a compensation slide plate is slidably connected to one end of the compensation slide, and a compensation steel rope body is fixedly connected to the compensation slide plate. The outer casing is slidably connected to the compensating steel rope body. One end of the compensating drive lever is fixedly connected to the compensating steel rope body, and the other end of the compensating drive lever is engaged in the compensating drive mounting plate. One end of the compensating drive rod body is fixedly connected to the compensating drive mounting plate, and the other end of the compensating drive rod body is fixedly connected to the compensating drive wedge. The compensating driven wedge is slidably connected to the compensating drive wedge. One end of the compensating valve ball push rod is fixedly connected to the compensating driven wedge, and the other end of the compensating valve ball push rod is fixedly connected to the compensating valve ball body. The compensating valve ball body is located inside the compensating valve ball sleeve, and the sleeve outer casing is located within the compensating valve... Outside the ball sleeve, a valve ball push rod spring is located outside the compensating valve ball push rod. The valve ball sleeve mounting bracket is fixedly connected to the compensating valve ball sleeve. The valve plug body is slidably connected to the compensating drive rod body. The compensating control valve mounting bracket is fixedly connected to the valve plug body. The middle part of the compensating drive lever is hinged to the upper part of the compensating control valve mounting bracket via a rotating shaft. An external spring is located outside the compensating drive rod body. The valve core sleeve is threadedly connected to the valve plug body. The compensating motor is connected to the compensating residual chlorine tank body via a liquid guide pipe. One end of the compensating inlet pipe is fixedly connected to the compensating residual chlorine tank body. The other end of the compensation inlet pipe is located inside the casing, one end of the compensation outlet pipe is fixedly connected to the casing, and the other end of the compensation outlet pipe is snapped into the compensation spray connector. The spray connector slide shaft is fixedly connected to the compensation spray connector, the compensation spray frame is fixedly connected to the spray connector slide shaft, one end of the main residual chlorine inlet pipe is snapped into the compensation spray connector, and the other end of the main residual chlorine inlet pipe is fixedly connected to the compensation residual chlorine tank body. The compensation temperature monitoring casing is fixedly connected to the compensation temperature monitoring body, and the compensation monitoring inner cavity connecting pipe passes through one side of the compensation temperature monitoring body. When the water temperature is high, the compensating double-stroke memory spring deforms due to heat, causing the compensating drive rod to move upward. The inclined surface of the compensating drive wedge then presses against the compensating driven wedge, pushing the compensating valve ball push rod to move and open the valve, releasing the residual chlorine reagent. When the water temperature is low, the compensating double-stroke memory spring resets, causing the compensating drive rod to move downward. The valve ball push rod spring resets, pushing the compensating valve ball to close the valve.

2. The secondary water supply device based on permissible residual chlorine according to claim 1, characterized in that: The adaptive rotary spraying assembly includes an adaptive rotary temperature monitoring body, an adaptive rotary temperature monitoring cavity, an adaptive rotary slide column located within the cavity, an adaptive rotary double-stroke memory spring located outside the slide column, an adaptive rotary slide plate slidably connected to one end of the slide column, an adaptive rotary steel cable body fixedly connected to the slide plate, an adaptive rotary steel cable outer shell located outside the steel cable body, an adaptive male contact fixedly connected to the steel cable body via a steel cable outer shell lever, an upper section of the adaptive rotary motor lead wire fixedly connected to the adaptive male contact, and an adaptive female contact... At the position adjacent to the adaptive male contact, the lower section of the adaptive rotary motor wire is fixedly connected to the adaptive female contact. Both the adaptive male and adaptive female contacts are located inside the adaptive contact mounting bracket. One end of the adaptive contact return spring is fixedly connected to the steel rope housing block, and the other end of the adaptive contact return spring is fixedly connected to the outside of the adaptive contact mounting bracket. The wire outside the adaptive rotary motor body is fixedly connected to the lower section of the adaptive rotary motor wire. The rotary motor drive gear is fixedly connected to the output end of the adaptive rotary motor body. The adaptive rotary monitoring inner cavity connecting pipe passes through the adaptive rotary temperature monitoring body, and the adaptive temperature monitoring housing is fixedly connected to the adaptive rotary temperature monitoring body.

3. A secondary water supply device based on permissible residual chlorine according to claim 2, characterized in that: The secondary water supply tank assembly includes a water supply tank body, a water supply tank cover, and a main water supply pipe. The water supply tank body is fixedly connected to the water supply tank cover, and the main water supply pipe is fixedly connected to the water supply tank body through a flange. A rotary motor mounting slot is provided on the upper part of the water supply tank cover, and a connecting head sliding shaft through hole is provided in the middle of the water supply tank cover. Rotary monitoring body mounting slots and compensation monitoring body mounting slots are respectively provided on both sides of the water supply tank body.

4. A secondary water supply device based on permissible residual chlorine according to claim 3, characterized in that: The compensation temperature monitoring body is located in the compensation monitoring body mounting slot. The compensation motor is fixedly connected to the water supply tank body through the mounting bracket. The spray connector slide shaft is rotatably connected to the connector slide shaft through the hole. The compensation monitoring inner cavity connecting pipe passes through the water supply tank body. The compensation control valve mounting bracket is fixedly connected to the water supply tank body.

5. A secondary water supply device based on permissible residual chlorine according to claim 4, characterized in that: The adaptive rotary motor body is fixedly connected in the rotary motor mounting slot. The rotary motor drive gear meshes with the teeth on the outside of the compensation spray connector. The adaptive rotary temperature monitoring body is located in the rotary monitoring body mounting slot. The adaptive rotary monitoring inner cavity connecting pipe passes through the water supply tank body. The adaptive contact mounting bracket is fixedly connected to the side of the water supply tank body.

6. A secondary water supply device based on permissible residual chlorine according to claim 5, characterized in that: One end of the compensating double-stroke memory spring is fixedly connected to the compensating slide plate, and the other end of the compensating double-stroke memory spring is fixedly connected to the inside of the compensating temperature monitoring body. One end of the compensating steel rope shell is fixedly connected to the compensating temperature monitoring body, and the other end of the compensating steel rope shell is fixedly connected to the compensating control valve mounting bracket. The compensating drive rod body passes through the compensating control valve mounting bracket. One end of the spring outside the drive rod body is fixedly connected to the compensating control valve mounting bracket, and the other end of the spring outside the drive rod body is located on the protrusion at the bottom of the compensating drive rod body. The compensating valve ball push rod passes through the valve ball sleeve mounting bracket. One end of the valve ball push rod spring is fixedly connected to the valve ball sleeve mounting bracket, and the other end of the valve ball push rod spring is fixedly connected to the compensating driven wedge. Both sides of the valve core sleeve are fixedly connected to the sleeve shell. The compensating spray is installed under the water supply tank cover.

7. A secondary water supply device based on permissible residual chlorine according to claim 6, characterized in that: One end of the adaptive rotary double-stroke memory spring is fixedly connected to the adaptive rotary slider, and the other end of the adaptive rotary double-stroke memory spring is fixedly connected to the inside of the adaptive rotary temperature monitoring body. One end of the adaptive rotary steel rope shell is fixedly connected to the adaptive rotary temperature monitoring body, and the other end of the adaptive rotary steel rope shell is fixedly connected to the outside of the adaptive contact mounting bracket.

8. A secondary water supply device based on permissible residual chlorine according to claim 7, characterized in that: Both sides of the compensation drive wedge are provided with compensation driven wedges. There are two compensation valve ball push rods, two compensation valve ball bodies, two compensation valve ball sleeves, two sleeve shells, two valve ball push rod springs, and two valve ball sleeve mounting brackets. The compensation drive rod body is arranged perpendicular to the compensation drive wedge, the compensation valve ball push rod is arranged perpendicular to the compensation driven wedge, and the compensation valve ball push rod is arranged perpendicular to the compensation valve ball body.

9. A secondary water supply device based on permissible residual chlorine according to claim 8, characterized in that: Both the compensating drive wedge and the compensating driven wedge are located inside the valve core sleeve, and both compensating valve ball bodies are located between the compensating valve ball sleeve and the valve ball sleeve mounting bracket.