FR3003340A1 - HOT WATER BOILER WITH SPIRALS - Google Patents

Abstract

The invention relates to a spiral boiler for heating water in a minimum of time and space. It consists of two curved spiral pipes A and B through which the water passes; two shielded resistors C and D curved in spirals which heat the walls of the spirals A and B, two elbows (5) and (10) which assemble the pipe (6) and the two spirals A and B. A shut-off valve (19) ) and a bicone T (20) which connect the spirals A and B to the pipe (16) by the bends (21) and (22). The boiler according to the invention is particularly intended for heating water.

Description

The present invention relates to a spiral hot water boiler. Compared to other boilers that need a particular location in the house, the spiral boiler does not need any special location, in addition the old boilers heat continuously to maintain the temperature of + or - 200 1 5 of water. The spiral boiler can be switched on or off at the second ready, using a switch, integral part of the power converter, essential for this type of boiler. The boiler consists of two annealed copper pipes, each spirally curved separately, and two armored resistors, spirally curved. The pipes will allow the water to pass. Shielded resistors will heat the pipes. Once assembled correctly together; a copper spiral, a spiral resistance shield, their side walls touch each other. Knowing that copper is a very good conductor of heat, the water passing through the pipes will be heated by the walls in contact with the armored resistance along the entire length of the two spirals that touch it. To limit the dimensions of the boiler, the spirals are placed in parallel and connected with the different elements. At one end of the first copper spiral, a "U" bend directed towards the inside of the spiral and a copper tube is placed to the exit of the spiral with two sleeves. At the outlet of the copper tube is mounted a second elbow "U" directed towards the second spiral, and with the help of two sleeves the copper tube is connected to the second spiral in parallel with the first spiral, by the 'outside. To ensure a perfect seal, we weld all the elements that made it possible to achieve this parallelism. A male nut will be introduced from one side of the second spiral to the hot water outlet, and another nut will be introduced on the side of the first spiral at the water inlet. To each nut is placed a sealing washer, then we will flare the pipe at each end and connect the various elements. To assemble the hot and cold water circuits, a stop valve (attached to the water inlet pipe) and a bicone "T" must be provided to connect the spirals using the second elbow "L". To all the parts that have just been connected, a seal will be inserted. At the hot water outlet and at the cold water outlet, the supply hoses allow them to be connected to the taps.

The accompanying drawings illustrate the invention: Figure 1 shows a pipe 012, copper, rolled into a spiral shape. Figure 2 shows an electrical resistance rolled into a spiral shape. Fig. 3 shows a copper pipe segment 012. Figure 4 shows two pipe elbows 012 in brass with different dimensions, bend in "U" shape. Figure 5 shows two copper sleeves for the pipe. Figure 6 shows the two spirals of Figure (1 and 2) assembled. To better understand, the 012 copper spiral is noted (A) and the electric spiral is noted (C). 10 (A) (1) get water, (A) (2) water outlet. (C) (3) pole +, (C) (4) pole -. FIG. 7 shows the parallel assembly with two spiral assemblies, the electric water (A B) (C D) at an elbow (10) and the sleeves (13; 14). To understand the two circuits (A B) (C D) have numbered the circuit (A B) 1, 2 6 7) and the circuit (C D) 3, 4, 8, 9). Figure 8 shows the final assembly before putting in a box, the pipe. To the left of the drawing are: the water inlet pipe (17) attached to the shut-off valves (19) by means of a female nut (18). The stop valve is fixed to the "T" bicone (20) using nuts (a). At the top of the "T" bicone (20) will fix the elbow (21) with the nut (b) to mount the assembly (A B, C D) which goes with the nuts (c). At the bottom of the "T" bicone (20) the elbow (22) will be secured with the nut (d) to mount with the nut (e) the pipe (16) by or will pass through. 'Cold water. Each water outlet is fixed a nut: hot water outlet (23), cold water outlet (24). Figure 9 shows the protective box with all the den to fix the final fixtures. To the left of the drawing is the location (25) where the nut (a) "T" bicone (20) is fixed. To the right of the drawing is the location (26) for the hot water outlet and the location (27) for the cold water outlet. Under the drawing one has the location (28) and (29) to fix the holds of two resistors. Inside the box is the element (30) which shares the cold water space of the hot water space. We can notice all the dimensions to respect to make this box. Figure 10 drawn to scale (ln) represents the dimmer switch (32) which is an important part of the boiler function. As the dimmer switch already exists I allow myself to give the dimension for my boiler. FIG. 11 represents the boxing of the boiler, where the two spiral resistors with the element (32) on the left and (33) on the right of the drawing are noted in parallel. The mounting of two sockets (34) and (35) and the protection (36) (37) which accompanies the electric wire (38) to the dimmer switch (39). In the right part of the drawing, there is a connection (40) fixed by means of a male nut (41) and the connection (42) fixed by means of a male nut (43). Figure 12 shows the five elements that are part of the protection box. In the drawings, the dimensions will be numbered separately from that of the boiler. All five elements are drawn in section, for a better understanding. Figure 12A shows the element (1) having three holes (M5) at the top, three holes (M5) at the bottom and two holes 018 (3; 4). Figure 12B shows the elements (5) where six holes (M5) are noted. Figure 12C shows the element (7) which shares the hot part of the box, the cold part of the box. The four M5s and the dimension of FIG. 12 are shown. FIG. 12D shows the element (9) with four threaded holes M5 and the hole (11) 033 which comes up to the water portion.

Figure 12E shows the element (12) which is mounted to the water outlet portion. Note the hole (14) for the cold water outlet pipe and the hole (15) for the hot water pipe, and the four M5 threaded holes. Figure 13A shows the part that will close over box.

Note the dimension (1) middle of 0 = 6 and the lateral part. Figure 13B shows the section (C D) to observe the representation of the passage holes 06 and the head cover 010, also all the dimensions to be respected. Figure 14 shows the bottom of the box. It has the same dimension as the holes.

Referring to the drawings of Figure (1), the piece is a spiral shaped spiral pipe spiral 012 spiral on a cylindrical piece 030 respecting the distance taken in the middle of two spirals of 24mm or 12mm, between the walls, on an L-336 mm + 24mm leaving a straight part of 12mm at each end to fix the nuts.

The desired shape "spiral" that reduces a pipe from 2000mm (2m) to 360mm. The pipe has a diameter of 012mm, corresponding to the sanitary installation to pass the water. Copper is a very good conductor of heat, what I am looking for and what is admitted for the installation of water. Referring to the drawing of Figure (2), the part is an electrical resistance modeled in 10 spirals which has the internal dimensions 030, dimension between two spirals (24mm) on a length L-342mm, which allows to fix it with the spirals in copper to form a set. By tightening the spirals they will touch on the whole length. As soon as the electric spiral is turned on, it will heat the copper pipe and the water inside it at the same time. Even if the water heats gently over the 2m (2000mm) length of the copper pipe, followed by mm / mm of the electrical resistance at the outlet, the water will have the desired temperature. To work better, the boiler will have two sets of spirals. These two sets will reduce the use of resistance and the use of the dimmer switch (Figure 10) that will control the electrical power and stop the boiler. To have cold water (FIG. 8), even if there is only one hose, water supply (17) after the shutoff valve (19) which makes it possible to regulate the volume of water, it is mounted the bicone T (20) and the elbow (22) which allows to mount the pipe (16) of cold water. Even if in all the drawings, the spirals are placed under the cold water pipe, it is because the spirals are the subject of the invention, in fact, the cold water pipe comes underneath. The principle of vases communicating in the opposite case, when you open the cold water tap, the hot water will flow at the same time.

25 The spiral boiler is intended especially for heating water, as needed for housing: kitchen, bathroom, garage. Knowing its size 492mm x 225 x 79, and the ease of being fixed (figure 14) in the kitchen, in the bathroom, in the garage, on different materials: stone, wood, faience, glass, metal, the boiler can find its place in a camper, a caravan, a cottage, a boat, a mobile home, ...

Claims (5)

CLAIMS1) Spiral hot water boiler characterized in that it comprises two spiral curved pipes A and B, a tube (6) which will allow to connect the spiral A and the spiral B in parallel using the elbow (5) and the elbow (10) and the sleeves (11,12,13,14) two shielded resistors C and D also curved in spirals, linked to the power variator (39). The "T bicone" (20) connects the two spirals to the pipe (16) using the elbow (21) and the elbow (22). The shut-off valve (19) is attached to the water inlet pipe and the "T-bicone" (20). 2) Boiler according to claim 1 characterized in that the spirals A and B are annealed copper 12. 3) Boiler according to claim 1 characterized in that the armored resistors are spread over the entire length of the spirals A and B and their side walls are touching. 4) Boiler according to claim 1 characterized in that the "T bicone" (20) has the role of distributing water to the spirals and the tube (16). 5) Boiler according to claim 1 characterized in that the power variator (39) required for this type of boiler, allows to choose the temperature.