RU223436U1 - Radiator Valve Insert - Google Patents

Abstract

The utility model relates to valves for liquid media, in particular to an insert valve for a heating radiator, and is intended to regulate the flow of water. A radiator valve containing a housing in which a spring-loaded rod is installed, at the end of which a locking element is installed that interacts with the seat of the valve outlet, while the valve body is connected to the outlet pipe, according to the utility model, the body is made hollow with the formation inside the working chamber, along the central the axis of which a spring-loaded rod is installed, and into which the coolant enters through a side hole. The proposed insert valve simplifies the valve design while achieving accurate and reliable operation at various pressures, in particular relatively high operating pressures and maintaining structural integrity during water hammer. It is also possible to install the valve in any heating radiator. 2 salary f-ly, 2 ill.

Description

The utility model relates to valves for liquid media, in particular to an insert valve for a heating radiator, and is intended to regulate the flow of water.

From the prior art, RF Patent No. 2201545, there is known an insert valve, which is inserted into the pipeline for liquid (for hot water) on the inlet pipe of the radiator of the heating system, i.e. a threaded portion (4) on the outside of the valve body (5) is screwed into a female-threaded plug-in connector. An insert piece (7) is secured to the lower end part (6) of the valve body (5) using a retaining ring (8). The locking ring, on one side, engages with the annular groove on the inner surface of the end part (6), and on the other hand, with the lower surface of the annular protrusion (9) of the insert part (7), resting on the inner shoulder of the end part (6). Therefore, the insert (7) can be considered to be part of the valve body (5). With its free end, the insert piece (7) extends into the inlet pipe inserted into the fluid pipeline and is sealed in the inlet pipe with an O-ring (11).

In the hole of the installation element (15) there is a valve rod (22), which can move in the axial direction. When a control element, such as the operating element of a thermostatic head, acts on the outer end of a pushrod (23) extending out through the gland (24), the valve stem can be moved axially by this pusher against the force of a return spring (25) located between the annular projection (26) of the valve stem (22) and an additional internal shoulder (27) in the hole of the installation element (15). At the end of the rod (22), protruding from the installation element (15), a valve locking part (28) made of elastic material is fixed, interacting with the valve seat.

From RF patent No. 2126510 a radiator valve is known, which contains a body, an inlet pipe, a seat, and a coaxially moving shut-off element. The latter forms the first throttling zone with the seat. The locking element is loaded with a spring in the opening direction. The rotary cylindrical bushing is made with a profiled end surface, loaded with a spring towards the annular surface enclosing the seat and installed to form a second throttling zone in the form of a gap between the annular surface and the end surface of the bushing and with the bushing blocking the outlet hole in the wall enclosing the bushing. The slot is formed by the annular surface enclosing the seat and the end surface of the bushing, displaced in the axial direction relative to the end of the seat.

From the international application WO 01/20207, registration date 03/22/2001, an insert valve for a sectional radiator is known, in which one radiator link has several links connected to each other using couplings that have partly left-hand threads, partly right-hand threads. The cavity of the first link is provided at the lower end with a feed connector. The built-in valve controls the transition of the coolant from the cavity to the cavity of the second link, which is connected to the return port by several more links. The valve has a body that has a screw-in part and a projection. The protrusion has a valve seat that interacts with a shut-off element that has pressure relief channels and is actuated by the valve stem from the thermostat nozzle (pusher). The cutout in the lip wall serves as the inlet channel, the pipe connecting to the valve seat serves as the outlet channel. A plate is attached to this pipe that supports the sealing washer. Thus, when screwing in the installation valve, the sealing washer is pressed tightly against the end surface of the pipe.

However, these valves have at least the disadvantage that they are technically complex and overloaded with parts, which does not ensure stable operation and protection of hydraulic equipment at relatively high operating pressures.

One of the objectives of the present utility model is at least to create a valve in which the mentioned disadvantages would be solved.

When using this utility model, a technical result is achieved consisting of simplifying the valve design while achieving accurate and reliable operation at various pressures, in particular relatively high operating pressures and maintaining structural integrity during water hammer, which makes it possible to install the valve in any heating radiator.

The specified technical result is achieved by a radiator valve, which contains a housing in which a spring-loaded rod is installed, at the end of which a locking element is installed that interacts with the seat of the valve outlet, and the valve body is connected to the outlet pipe.

The difference between the claimed valve design is that the body is hollow, forming a working chamber inside, along the central axis of which a spring-loaded rod is installed, and into which the coolant enters through a side hole.

An elastic sealing membrane is installed at the end of the outlet pipe.

The locking element is made in the form of a spool plate.

Next, the utility model will be described with reference to the drawings, which show:

in fig. 1 - longitudinal section of the proposed radiator valve;

in fig. 2 - diagram of the operation of the valve in the heating radiator.

The drawings indicate the following positions

No. Name Material 1 Pusher Carbon steel 2 Spring Stainless steel 3 Ring sealing Nitrile butadiene rubber 4 Stock Stainless steel 5 Locking element Brass 6 Sealing membrane Nitrile butadiene rubber 7 Pre-setting nut Plastic 8 Valve body Brass 9 Spool gasket Nitrile butadiene rubber 10 Outlet pipe Brass, powder coated - white eleven Inlet 12 Saddle 13 Outlet 14 Working chamber 15 Radiator input unit 16 Nut for presetting on valve 17 The upper section of the pipe of the radiator section 18 Vertical radiator tube 19 The lower section of the pipe of the radiator section 20 Connecting sleeve 21 Partition

The radiator valve contains a housing 8, in which a spring-loaded rod 4 is installed, driven by a pusher 1. At the end of the spring-loaded rod 4, a locking element 5 is installed, made in the form of a spool plate.

The valve body is made hollow with a working chamber 14 formed inside. At least one outlet hole 13 is made on the side of the body.

A spring-loaded rod 4 is located along the central axis of the working chamber 14, around which a spring 2 is placed, ensuring the working position of the rod.

This design of the valve with one chamber, a rod and a spring simplifies the design, but makes it stable during operation.

At the end of the rod 4 there is a locking element 5, which interacts with the seat 12, while the valve body is connected to the outlet pipe 10.

In the presented version, the valve sleeve, like the entire outer valve body, is solid and made of cast brass grade CW614N.

An elastic sealing membrane 6 is installed at the end of the outlet pipe 10.

The valve seat 12 and the inlet hole are made integral with the body, for example, made of brass, which increases the strength of the structure.

In a preferred embodiment of the utility model, the valve body and bushing are made in one piece, for example, from brass, which increases the strength of the structure.

The valve insert can be installed in any heating radiator in which the process connection thread is equal to one inch (G1”, G1”LH) due to the universal sealing membrane 6. The sealing membrane 6 fits all connecting sleeves of heating radiators. Due to this sealing membrane, tightness is achieved between the first and subsequent sections of the heating radiator when the shut-off element 5 of the valve is in the “closed” position.

The valve operates as follows.

The coolant flow is indicated by red and blue arrows in Fig. 2.

- the coolant passes through the input unit 15 of the first section of the radiator,

- passes through the vertical tube of section 18,

- enters the valve working chamber through the side inlet 11 of the valve,

- further, the coolant flow is regulated by the shut-off element 5, which is inextricably linked to the pusher 1 through a spring-loaded rod 4,

- the coolant from valve chamber 14 enters the second section of the heating radiator through the outlet pipe and is distributed through subsequent sections to the entire heating radiator,

- the coolant transfers thermal energy through the metal walls of the radiator into the environment around the radiator.

Valve inserts are available in right-hand and left-hand threaded versions, respectively, with right-hand or left-hand inch threads.

The radiator section is part of a heating radiator made of interconnected sections. This utility model can be used with any heating radiators in which the process connection thread is one inch (G1”, G1”LH) and the number of sections is more than two.

The heating radiator section includes the upper section of the pipe of the radiator section 17, to which the lower section of the pipe of the radiator section 19 is rigidly connected by the vertical pipe of the radiator 18.

In the upper and lower tubes there are threaded connecting sleeves 20, each of which connects adjacent upper and adjacent lower tubes of the first section and the subsequent second section.

The upper section of the pipe of the radiator section 17 and subsequent ones form the upper line, the lower section of the pipe of the radiator section 19 and subsequent ones form the lower line for the passage of the coolant. A partition 21 is installed in the lower line between the first and second sections of the radiator, which is a cylindrical plug installed in a threaded connecting sleeve 20. The partition is designed to prevent direct flow of coolant along the lower line. The first section of the radiator presented in this description is one of its two outer sections (right or left).

The valve is installed in the first section of the heating radiator, in its upper line, and more specifically in the upper section of the tube of the radiator section 17 of the first radiator section on the outside of this tube and the radiator.

The coolant flow can be regulated as follows:

- using the presetting nut on valve 16 with a special presetting wrench or a wrench No. 13. Each number on the presetting nut corresponds to its own range of coolant flow, i.e. the amount of coolant fluid passed through the valve; intermediate values are not allowed. The value "6" corresponds to the normal setting (factory setting).

- by turning the plastic rotary cap, which is included in the valve insert kit, twisting clockwise along the external thread of the valve insert M30x1.5 mm, the cap moves the pusher 1, the pusher moves the spring-loaded rod 4, which is inextricably linked with the locking element 5. The valve shut-off element can be set in this way from the "fully open" position to the "fully closed" position;

- when equipped with a thermostatic valve with a threaded connection M30x1.5 mm (hereinafter referred to as the “Thermal Valve”), the coolant flow is regulated by the thermal valve in accordance with the specified temperature ranges required to regulate the ambient temperature around the radiator. The design of this valve allows for operation with any temperature control equipment with an installation connection designed for M30x1.5 mm thread. The moving element of the temperature control equipment interacts directly with pusher 1.

In the presented utility model, the valve sleeve, like the entire outer valve body, is solid and made of cast brass grade CW614N.

The design of the valve sleeve of analogues contains technical elements made of metals with low corrosion resistance (for example, cold-rolled steel), which directly interact with the coolant (for example, hot water), which reduces the service life of the structure and has unpredictable consequences for all heating systems after 3-5 years operation. In the proposed design, all technical elements in contact with the coolant are made of cast brass grade CW614N, as well as nitrile-butadiene rubber (NBR).

Due to the proposed design, the radiator valve is able to withstand heavy loads, including water hammer, occurring during operation, without damage and without reducing performance properties. The working pressure tested on the manufactured sample of the utility model was 16 bar, the Maximum test pressure was 32 bar, and the Maximum design pressure was 140 bar.

Claims (3)

1. A radiator valve containing a housing in which a spring-loaded rod is installed, at the end of which a locking element is installed that interacts with the seat of the valve outlet, while the valve body is connected to the outlet pipe, characterized in that the body is made hollow to form a working chamber inside, along the central axis of which a spring-loaded rod is installed, and into which the coolant enters through a side hole. 2. The valve according to claim 1, characterized in that an elastic sealing membrane is installed at the end of the outlet pipe. 3. The valve according to claim 1, characterized in that the shut-off element is made in the form of a spool plate.