RU2119617C1 - Rotary heater - Google Patents

Abstract

FIELD: heat engineering. SUBSTANCE: rotary heater includes thermal protective member to avoid direct access of heat radiated by combustion chamber and to promote radiation of heat outside. Heater is also provided with guides which are open in center. They are secured to upper surface of thermal protective member to give required direction for air flow, fan with motor and supporting device secured on upper surface of supporting device and used for mounting the motor. EFFECT: simplified manufacture; increased productivity and ease in maintenance; reduction of noise and vibrations. 3 cl, 6 dwg

Description

 The present invention relates to a rotary heater with a forced convection ventilation motor, and in particular a rotary heater that damps the vibrations and noise produced by the ventilation motor and facilitates assembly and repair work.

 In conventional rotary heaters, as shown in FIG. 1 and 2, the heater body 1 is placed in the upper part of the base 15 for positioning a combustion chamber emitting heat therein, and heat is supplied from the combustion chamber 2, and a plurality of holes 1a for air intake are formed on the periphery of the heater body 1.

 In addition, the plate of the heat shield 3 for protection against heat radiated by the combustion chamber 2 is located in the upper inner part of the heater body 1, where it is assembled and secured by several fixing screws 4. The upper plate 5 is fixed by fixing screws 4 on the upper portion of the heater 1 observing a certain distance from the shielding plate 3.

 The motor 7, the rotary fan 6, is attached to the top plate 5 in such a way as to prevent the heat emitted from the shield plate 3 from rising to the top plate 5; however, the radiated heat is removed through the openings 1a of the heater body 1.

 In other words, the upper end of the motor 7 is inserted into the hole 8a to accommodate the motor, which is formed in the center 7 of the mounting element of the motor 8, welded to the inner lower side of the upper plate 5. At the same time, using the screw holes 8b formed in the mounting element of the motor 8, the motor is assembled and is fastened with fastening bolts 10 by means of rubber shock absorbers 9 inserted into the cut-out recesses 7b in a reinforcing element 7a protruding along the entire periphery of the motor 7.

 On the axis of the motor 7b, located under the motor 7 and driven by the motor force of the motor 7, sequentially insert the sleeve 11, the first washer 12, the fan 6 and the second washer 13, which are secured by a fixing bolt 14 to prevent fan displacement.

 A conventional rotary heater, designed in this way, contains a motor mount, fixed to the lower inner part of the upper part by welding, after which the motor 7 and the fan are attached to the motor mount 8.

 Thus, for fastening the motor, fan and other elements, the fastening element of the motor 8 is welded to the top plate 5, which requires additional measures during assembly in connection with welding, thereby reducing productivity, and causes difficulties in subsequent maintenance.

 Moreover, due to the fact that the motor mount member 8 and the top plate are completely welded together to mount the motor, excessive noise and vibration produced by the motor 7 and fan 6 cannot be drowned out and fall to the consumer’s part, which leads to various problems, including deterioration in the quality of the heater.

 Accordingly, the present invention is proposed to solve the above problems, and its purpose is to produce a rotary heater in which the motor is attached to the heater body by screw fastening to reduce the assembly steps, in particular the welding step, so that productivity can be improved and subsequent maintenance can be relieved; furthermore, the vibrations and noises produced by the motor and fan can be damped and the quality of the product improved.

To achieve these goals of the present invention, a rotary heater in accordance with the invention comprises:
- a heat shield to protect against heat radiated by the combustion chamber and to radiate heat,
- guiding means attached to the upper part of the heat-shielding means and opening in the center for direction against air and
- support means attached to the top of the guide means to provide support for the motor.

For a clearer understanding of the nature and objectives of this invention should refer to the following detailed description in connection with the accompanying drawings, in which:
FIG. 1 is an internal structural drawing illustrating an internal structure equipped with a forced convection ventilation motor installed in a conventional type rotary heater;
FIG. 2 is an analytical cross-sectional view illustrating a partially analyzed conventional type heater;
FIG. 3 is an internal structural drawing illustrating an internal structure of a heater according to a first embodiment of the present invention, equipped with a forced convection ventilation motor;
FIG. 4 is an analytical cross-sectional view illustrating a partially analyzed heater in accordance with a second embodiment of the present invention;
FIG. 5 is an analytical cross-sectional view illustrating a partially analyzed rotary heater in accordance with a second embodiment of the present invention; and
FIG. 6 is an analytical cross-sectional view illustrating a partially analyzed rotary heater in accordance with a third embodiment of the present invention.

 Here, the first embodiment of the invention will be described in detail with reference to the accompanying drawings.

 In FIG. 3 and 4, numeral 21 denotes a heater body with a silver-plated heat-resistant surface that has rounded corners and is stamped in the shape of a rectangular tub. It houses a combustion chamber 23 to produce maximum heat. It is fixed on the upper part of the base 22.

 Around the periphery of the heater body 21, a plurality of holes 21a are formed so as to release the superheat produced by the combustion chamber 23 and at the same time draw in ambient air.

 Above the combustion chamber 21 is a heat-shielding element 24 mounted with fixing screws 38 to protect against heat radiated by the combustion chamber 23 and to radiate incoming heat.

 One end of the staples 25 is fixed at the corners of the heat shield 24 by welding, and threaded holes 25a are formed at the other end of the staples so that the guiding means 26 (explained below) can coincide with the threaded holes when screwed together.

 Guide means 26 having approximately the same size as the heat shield element 24 are located on the upper surface of the heat shield element so as to be on the upper surface of the brackets 25 fastened to the top surface of the heat shield element 24.

 In other words, the threaded holes 26a corresponding to the threaded holes 25a formed in the brackets 25 are formed on the upper surface of the guide means 26 so that the threaded holes 26a of the guiding means 26 and the threaded holes 25a of the brackets 25 can match for fastening them with the clamping nuts 27 and for fastening the guide means 26 with brackets 25.

 In addition, closer to the center of the threaded holes 26a, threaded holes 26b are formed on the upper part of the guide means 26 so that the means supporting the motor (explained below) can be fastened with screws.

 In the center of the upper part of the guide means 26, an opening 26c is formed for sucking in atmospheric air so that the surrounding air can be sucked in through the holes 21a formed in the heater body 21. In addition, a series of holes 26e are made around the hole 26c for additional air intake.

 The motor support device 30 is mounted on the upper surface of the guide means 26 to support and install the motor 29 with a fan 28 on its axis 29a and to draw in ambient air.

 At the corners of the support device 30, threaded holes 30b are made in line with the threaded holes 26b of the guide means 26 and the support device 30 is fastened to the upper surface of the guide means using the clamping screws 31.

 The support device has a continuous upper surface 30c and side walls 30d, a motor-shaped hole 30e is formed in the center of the upper surface 30c, and threaded holes 30f are formed on the sides of the hole 30e. Along the edges of the upper surface 30c, longitudinal openings 30g are formed for sucking in ambient air, and openings 30h for also drawing in air are formed in the walls 30. On one side of the suction openings 30h, induction elements 30i are bent to prevent turbulence during suction of air through these openings, and a continuous strip 30a is retained under the openings in the lower part of the side wall 30d.

 The motor 29 is inserted into the hole 30e of the support device 30 in its upper part, and at the same time, by aligning the threaded holes 30f formed on the upper surface 30c of the support device 30, the motor 29 is secured with bolts 31 through rubber shock absorbers 32 inserted into the cut-out recesses 29c in a reinforcing element 29b protruding peripherally from the center of the motor 29.

 Next, the sleeve 33, the washer 34, the fan 28 and the other washer 35 are mounted in this order on the axis 29a of the motor 29, and the axis 29a of the motor is fixed with a clamping nut 36 to avoid bias.

 In this situation, the fan 28 is located between the heat-shielding element 24 and the guide means 26.

 At the same time, the upper plate 37 covers the upper open part of the heater body 21 from the outside, and the upper plate 37 and the heater case are mutually fastened with clamping bolts 38.

 Next, the operation of the heater thus constructed in accordance with the first embodiment of the present invention will be explained.

 As explained in FIG. 3 and 4, as soon as the main switch of the control system located on the base 22 (not shown) is turned on to produce and emit superheat from the combustion chamber 23, the superheat is released outside through the hole 21a formed on the heater body 21 to heat exchange the ambient air with hot air.

 The rising superheated air strikes into the heat-shielding element 24 mounted inside the heater body and transfers heat to this element, so that heat radiation subsequently comes from the heat-shielding element 24.

 At this moment, when the start button of the motor 29 installed in the upper part of the heater body is turned on in the control system installed on the base 22, the motor axis 29a starts to rotate under the action of the motor force of the motor 29, driving the fan 28 mounted on the end of the axis 29a motor.

 Accordingly, the ambient air is sucked into the longitudinal holes 30g and the suction hole 30h of the support device 30 through the holes 21a of the heater body 21 formed between the guide means 26 and the top plate 37. The ambient air is sucked into the inside of the support device 30 and, due to the rotation effect of the fan 28, is sucked into the suction hole 26c atmospheric air guide means 26.

 Next, the atmospheric air drawn into the suction hole of the ambient air 26c strikes the upper surface of the heat-shielding element under the action of the fan 28 rotated by the motor 29, and the atmospheric air turns into hot air under the influence of superheat emitted by the heat-shielding element 24.

 Hot air is supplied to the atmosphere through the openings 21a of the heater body 21, which are made between the guide means 26 and the heat-shielding element 24, thereby exchanging atmospheric air with the hot air.

 At the same time, the motor 29 is attached to the support device by means of clamping screws, and the support device 30 for supporting the motor 29 is firmly attached to the upper part of the guide means 26 by the clamping screws so that the vibration and noise produced by the motor are transmitted in a damped form to the heater body 21 through supporting device 30 and guide means 26, thereby reducing the negative impact of vibration and noise on the consumer and improving the quality of the product.

 Moreover, due to the fact that the supporting device 30 for mounting the motor 29, the guide means 26 and the heat shield 24 are fastened with bolts and nuts, the repair and assembly are greatly facilitated, which leads to increased productivity and easier maintenance.

 Next, a second embodiment of the present invention will be described with reference to FIG. 5.

 This embodiment of the present invention differs from the first embodiment in that two longitudinal slots 30g 'are formed on the upper surface of the supporting device 30', two suction slots 30h 'are formed on the side wall 30d', and two inductive elements 30i 'are formed on one side of each slot to prevent twists.

 In other words, the second embodiment of the invention comprises more than two longitudinal slots 30g ′ and suction slots 30h ′ for use with all support devices 30 ′ supporting the motor 29.

 The third embodiment of the invention will be considered in conjunction with figure 6.

 This embodiment of the invention differs from the first and second variants in that the supporting device 30 ″ is made in the form of a rectangle in which longitudinal slots 30g ″, suction slots 30h ″ and inductive elements 30i ″ are formed.

 In other words, this embodiment of the invention can be used with all types of devices 30 ″ supporting the motor, having the function of sucking in atmospheric air and containing longitudinal slots 30 g ″, suction slots 30 h ″ and the like.

 As can be seen from the previous discussion, the rotary heater according to the present invention has a structure in which the means for fastening the motor by means of a screw connection are attached not to the top plate, but to the upper surface inside the heater body, and the guide element and the heat shield element are also located inside the heater case screw connections, which facilitate manufacturing, increase productivity and simplify maintenance. In addition, damping noise and vibration creates a pleasant atmosphere for the consumer.

Claims (3)

 1. A rotary heater comprising a heat-shielding element, preventing direct access of heat emitted by the combustion chamber, and contributing to the emission of heat outward, guiding means attached to the upper surface of the heat-shielding element and providing direction of air flow, and a fan with a motor, characterized in that the heater is equipped with supporting device, mounted on the upper surface of the guide means and intended for mounting the motor, and the guide means are made open and in the center.  2. The heater according to claim 1, characterized in that the guide means are made with a hole for suctioning atmospheric air in their center, and they also have a number of holes around the hole for suctioning ambient air.  3. The heater according to claim 1, characterized in that the fan rotating from the motor is located in the cavity formed between the guiding means and the heat shield element.

Images