RU67592U1 - DRINKING WATER CONSUMPTION SYSTEM (OPTIONS) - Google Patents

Abstract

The utility model relates to water supply systems that ensure uninterrupted supply of drinking water to consumers in residential buildings, office buildings and other premises. A complex pipeline is used to supply drinking water, the reception line of which is connected to the cold water supply pipe, which is part of a centralized water supply system. Cold water taken through the line passes through its after-treatment unit to the quality of drinking water and enters the distribution pipeline. Then, through the branches of the distribution pipeline, drinking water is supplied to the places of consumption. At any time, by opening the tap, the consumer can select the amount of drinking water he needs from the system. The water supply system according to the second and third embodiments is used in cases where drinking water is delivered in mobile containers and pumped to a storage tank or tanks from which it enters the branches of the distribution pipeline and is taken as necessary by consumers. 3 n.a. and 4 z.p. f-ly, 2 ill.

Description

The utility model relates to the field of construction, namely to water supply systems that provide drinking water to consumers in residential buildings, office buildings and other premises.

A known system of water supply to consumers with drinking water, comprising a distribution pipe connected to storage and consumable containers placed everywhere in the building at the place of water consumption, by means of supply pipelines with valves and water meters, and also containing a mobile dispensing container with a flexible pipe for connecting the mobile tank to distribution piping and local control unit for bottling water (RU 2288999 C1, 2006). The specified technical solution is the closest analogue to the claimed utility model. This water supply system provides for the use of a large number of storage and expendable tanks, the amount of which depends on the number of drinking water consumption places. This greatly complicates and increases the cost of the water supply system, and also creates inconvenience for consumers due to the need to install, for example, in each apartment (if we are talking about the water supply to a residential building) a bulky storage and consuming capacity, which takes up a lot of space, placed at an unusually high level in relation to to the consumer and requiring special (i.e. non-traditional) methods of water withdrawal from this tank. In addition, since the selection of water from storage-consumable containers is uneven at the places of consumption (i.e., water in some containers may be completely consumed, and in others only partially), it is necessary to use a special device to collect and process information about the amount consumed water by each consumer to ensure timely replenishment of storage and consumable containers. The supply of consumers with drinking water using the specified known system is preferred for those buildings that are not connected to a centralized water supply. However, the system used for these cases under the specified patent requires the transport of drinking water

means with a mobile tank with short intervals between rides, which, in the presence of interruptions in transport and other factors that negatively affect the timely delivery of water in a mobile tank, can lead to interruptions in the supply of drinking water to consumers.

The inventive utility model is aimed at solving the problem of creating such a water supply system, which would ensure the flow to the place of consumption of high-quality drinking water that does not require additional purification by the consumer.

To solve this problem, three options for the implementation of the water supply system are proposed.

The technical result that can be achieved by implementing a utility model for each implementation option is to simplify the design of the water supply system and reduce its cost, significantly increase the convenience of its maintenance and reduce maintenance costs, as well as ensure uninterrupted supply of drinking water to consumers.

To achieve the specified technical result, according to the first embodiment, a drinking water supply system for consumers comprising a cold water supply pipe that has been treated in a centralized treatment station, at least one unit for purifying cold water to a drinking water quality and an integrated drinking water supply pipe are provided to consumers, including a receiving line connected to the cold water supply line, a supply line connected to the receiving line through the after-treatment unit Ki cold water to the quality of drinking water, and distribution pipe. The distribution pipeline communicates with the supply line and has branches for the number of places of consumption for supplying drinking water to the outlet taps installed at the place of drinking water intake by consumers and interlocked with water meters. The unit for purification of cold water to the quality of drinking includes at least one filter module connected to the outlet section of the receiving line, at least one storage tank connected through shut-off valves to the filter module, and at least one bactericidal the lamp. The filter module and storage tank are also connected through the pump

a station for pumping filtered water into the supply line and a bactericidal lamp with an inlet portion of the supply line.

The system has a block of instrumentation and automation connected to the filter module, to the stop valves of the storage tank, to the meters and to the stop valves with an electric drive, designed to disconnect consumers.

Connecting the intake line of the complex drinking water supply line to consumers directly to the cold water supply line and connecting the reception line to the supply line and, therefore, to the distribution system through the cold water after-treatment unit to the quality of drinking water allows you to receive drinking water of the required quality directly in the centrally supplying system buildings for various purposes with cold water. This allows us to solve the problem of uninterrupted centralized delivery of drinking water to consumers using a system that is simple in design and easy to maintain.

To achieve the specified technical result, according to the second embodiment, a drinking water supply system for consumers is proposed, comprising a distribution pipe, a storage tank, a pumping station for pumping drinking water from the storage tank to a distribution pipe, and at least one bactericidal lamp located in the network distribution pipeline. The distribution pipeline has branches for the number of consumers for the supply of drinking water to the outlet taps installed at the place of drinking water intake by consumers and interlocked with water meters. The storage tank is made with connection to a mobile tank with drinking water.

The system has a block of instrumentation and automation connected to the shut-off valves of the storage tank, to the meters and to the shut-off valves with an electric drive, designed to disconnect consumers.

In the third embodiment, a water supply system is proposed comprising a distribution pipe and at least two storage tanks. The distribution pipeline has branches for the number of consumers for

supply of drinking water to the outlet taps installed at the place of drinking water withdrawal by consumers and interlocked with water meters. Each storage tank is made with the possibility of connecting through shut-off valves to a mobile tank that supplies drinking water to the storage tanks. The system includes a pumping station that provides the transfer of drinking water from storage tanks to the distribution pipe, and at least one bactericidal lamp located in the distribution pipe network. Storage tanks are parallel or sequentially interconnected through valves.

The system has a block of instrumentation and automation connected to the shutoff valves of the storage tanks, to the meters and to the shutoff valves with an electric drive, designed to disconnect consumers.

Use in the proposed water supply system according to the second and third options (in comparison with the closest analogue) of the total storage capacity (total storage capacities) made (made) with the possibility of connecting through shut-off valves to the mobile capacity supplying drinking water to the system and providing drinking water water from the total storage tank (s) to consumers allows for a single delivery of water in a mobile tank to provide a significant reserve of drinking water stored in a storage tank spacers (tanks). Due to this, the number of vehicle trips required to deliver mobile tanks to the water supply system is significantly reduced, which contributes to the uninterrupted supply of drinking water to consumers. In addition, the proposed implementation of the system eliminates the need to install a large number of containers at the places of consumption (compared with the closest analogue), which simplifies the design of the system and increases the convenience of its maintenance.

The utility model is illustrated by drawings, where:

- figure 1 shows a diagram of a water supply system according to the first embodiment of its implementation;

- figure 2 is a diagram of a water supply system according to the third embodiment of its implementation.

The water supply system shown in FIG. 1 comprises a cold water supply pipe 1 and an integrated drinking water supply pipe to consumers. Pipeline 1 is part of a centralized water supply system for consumers. In this case, the water entering the consumers through the pipeline 1, is pre-treated in a centralized treatment plant (not shown). The complex pipeline for supplying drinking water to consumers includes a intake line 2, a supply line 3 and a distribution pipe 4. The intake line 2 is connected to the cold water supply line 1. The supply line 3 is connected to the reception line 2 through the block 5 of post-treatment of cold water to the quality of drinking water. Distribution pipeline 4 communicates with the supply line 3 (i.e., is a continuation thereof) and has branches 6 according to the number of places of consumption 7, where drinking water is supplied to the outlet taps 8 and is directly selected by consumers as necessary. Monitoring of water flow is carried out by means of counters 9 (individual meters designed to present invoices for payment).

Block 5 of purification of cold water to the quality of drinking water can be located in the zone of the central treatment plant, or in the microdistrict, or inside the building (in the basement, attic or in the intermediate room). Block 5 includes a filter module 10 connected to the outlet portion 11 of the receiving line 2, a storage tank 12 and a bactericidal lamp 13. The storage tank 12 is connected through a stop valve 14 to the filter module 10. In addition, the filter module 10 and the storage tank 12 are connected through the pumping station 15, which serves to pump filtered water into the supply line 3, and a bactericidal lamp 13 - with the inlet section 16 of the supply line 3. The system is equipped with a block 17 of instrumentation and automation connected to the filter module 10, to the lock fittings 14 of the storage tank 12, to the water meters 9 and to the shutoff valves 18 with an electric drive, which is designed to shut off the consumer in case of debt or during preventive maintenance.

Water supply of consumers with drinking water when using a system made according to the first embodiment is as follows. For the preparation and supply of drinking water to its places of consumption, a central water supply system is used. Cold water passing through the pipeline 1 (which is an integral part of the central water supply system) is selected for the subsequent receipt of drinking water by the intake line 2 of the integrated pipeline and is supplied to the cold water after-treatment unit 5 to the quality of drinking water. Here, cold water enters the filter module 10, where it is gradually cleaned to the quality of drinking water. The purified water is sent to the storage tank 12, from where, using the pump station 15, through the supply line 3 and then through the branches 6 of the distribution pipe 4, it is supplied to the places of consumption 7. At any time, by opening the tap 8, the consumer can take the amount of drinking water he needs from the system . The selection of cold water from the pipeline 1 is carried out by the consumer when opening the taps 19.

The water supply system shown in FIG. 2 corresponds to a third embodiment. The system can be used to supply drinking water in cases where such water is supplied to buildings supplied with cold and hot water through appropriate pipelines, which are part of the general system of centralized water supply to consumers. However, such a system can also be used to supply drinking water to such residential buildings (for example, in rural areas) that do not have a connection to a common centralized water supply system. The water supply system of FIG. 2 contains a distribution pipe 4 and storage tanks 12 connected to it through the intermediate pipe 20. The storage tanks 12 are connected in parallel or in series through shut-off valves 21. The intermediate pipe 20 runs along the hot and cold water supply pipelines. The distribution pipe 4 has branches 6 according to the number of places of consumption 7, where drinking water is supplied to the outlet taps 8 and is directly taken by consumers as necessary. The control of water flow is carried out by means of counters 9. Storage tanks 12 are configured to

connecting through a stop valve 22 to a mobile tank with drinking water delivered by a vehicle (not shown).

The pump station 15 is used for pumping drinking water from the storage tanks 12 into the distribution pipe 4. In the network of the distribution pipe 4 is a bactericidal lamp 13.

The system is equipped with a block 17 of instrumentation and automation connected to shut-off valves 14 of storage tanks 12, to water meters 9 and to shut-off valves 18 with an electric drive, which is designed to shut off the consumer in case of debt or during preventive maintenance.

The selection of cold water from the pipeline 1 is carried out by the consumer when opening the taps 19.

The water supply system according to the second embodiment is made similar to the system shown in figure 2, with the only difference being that it uses only one storage tank 12.

Water supply of consumers with drinking water when using a system made according to the second and third options is as follows.

Drinking water is delivered in a mobile hygienically clean sealed container (s) installed on the vehicle. Using a pump installed in the transfer compartment of the mobile tank, drinking water is supplied through a flexible pipe for pouring water (not shown) from the mobile tank to the storage tank (storage tanks) 12. After filling the storage tank (or all storage tanks, when at least two) disconnect the flex. Water from the storage tanks 12 is pumped through the pumping station 15 to the distribution pipe 4. Then, through the branches 6 of the distribution pipe 4, drinking water is supplied to the places of consumption 7. At any time, by opening the tap 8, the consumer can select the amount of drinking water he needs from the system. Storage tanks are replenished as necessary with drinking water from mobile tanks.

Claims (7)

1. A drinking water supply system for consumers, comprising a cold water supply pipe that has been treated in a centralized treatment plant, consumers, at least one unit for purifying cold water to drinking water quality, an integrated drinking water supply pipe to consumers, which includes a receiving line connected to a cold water supply pipe, a supply line connected to a reception line through a cold water after-treatment unit to the quality of drinking water, and a distribution pipe communicating with a supply line and having branches according to the number of places of consumption for supplying drinking water to the outlet taps installed at the place of drinking water consumption by consumers and interlocked with water meters, and a pumping station for pumping filtered water into the supply line, while the aftertreatment unit includes, at least one filter module connected to the outlet section of the reception line, at least one storage tank connected through shutoff valves to the filter module, and at least one bactericidal lamp moreover, the filter module and the storage tank are connected through the pump station and the bactericidal lamp to the inlet section of the supply line. 2. The system according to claim 1, characterized in that it has a block of instrumentation and automation connected to the filter module, to the stop valves of the storage tank, to the meters and to the stop valves with an electric drive, designed to turn off the consumer. 3. A water supply system for consumers with drinking water, comprising a distribution pipe having branches for the number of consumers for supplying drinking water to the outlet taps installed at the place of drinking water consumption by consumers and interlocked with water meters, a storage tank configured to be connected to mobile valves through valves potable water tanks, a pumping station for pumping potable water from a storage tank to a distribution pipe, and at least m Here, one bactericidal lamp located in the distribution pipe network. 4. The system according to claim 3, characterized in that it has a block of instrumentation and automation connected to the shut-off valves of the storage tank, to the meters and to the shut-off valves with an electric drive, designed to turn off the consumer. 5. A drinking water supply system for consumers, comprising a distribution pipe having branches for the number of consumers for supplying drinking water to outlet taps installed at the place of drinking water withdrawal by consumers and interlocked with water meters, at least two storage tanks, each of which is made with the possibility of connecting through shut-off valves to a mobile tank with drinking water, a pumping station that provides the transfer of drinking water from storage tanks in the distribution itelny conduit and at least one germicidal lamp disposed in the distributor pipe network. 6. The system according to claim 5, characterized in that the storage tanks are parallel or sequentially interconnected through valves. 7. The system according to claim 5, characterized in that it has a block of instrumentation and automation connected to the stop valves of the storage tanks, to the meters and to the stop valves with an electric drive, designed to disconnect consumers.